January 2011, Rev. 1 © 2011 Fluke Corporation. All rights reserved. Specifications are subject to change without notice. All product names are trademarks of their respective companies. ProSim ™ 6/8 Vital Signs Simulator Users Manual
January 2011, Rev. 1 © 2011 Fluke Corporation. All rights reserved. Specifications are subject to change without notice. All product names are trademarks of their respective companies.
ProSim™ 6/8 Vital Signs Simulator
Users Manual
Warranty and Product Support
Fluke Biomedical warrants this instrument against defects in materials and workmanship for one year from the date of original purchase OR two years if at the end of your first year you send the instrument to a Fluke Biomedical service center for calibration. You will be charged our customary fee for such calibration. During the warranty period, we will repair or at our option replace, at no charge, a product that proves to be defective, provided you return the product, shipping prepaid, to Fluke Biomedical. This warranty covers the original purchaser only and is not transferable. The warranty does not apply if the product has been damaged by accident or misuse or has been serviced or modified by anyone other than an authorized Fluke Biomedical service facility. NO OTHER WARRANTIES, SUCH AS FITNESS FOR A PARTICULAR PURPOSE, ARE EXPRESSED OR IMPLIED. FLUKE SHALL NOT BE LIABLE FOR ANY SPECIAL, INDIRECT, INCIDENTAL OR CONSEQUENTIAL DAMAGES OR LOSSES, INCLUDING LOSS OF DATA, ARISING FROM ANY CAUSE OR THEORY.
This warranty covers only serialized products and their accessory items that bear a distinct serial number tag. Recalibration of instruments is not covered under the warranty.
This warranty gives you specific legal rights and you may also have other rights that vary in different jurisdictions. Since some jurisdictions do not allow the exclusion or limitation of an implied warranty or of incidental or consequential damages, this limitation of liability may not apply to you. If any provision of this warranty is held invalid or unenforceable by a court or other decision-maker of competent jurisdiction, such holding will not affect the validity or enforceability of any other provision.
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Notices
All Rights Reserved Copyright 2010, Fluke Biomedical. No part of this publication may be reproduced, transmitted, transcribed, stored in a retrieval system, or translated into any language without the written permission of Fluke Biomedical.
Copyright Release Fluke Biomedical agrees to a limited copyright release that allows you to reproduce manuals and other printed materials for use in service training programs and other technical publications. If you would like other reproductions or distributions, submit a written request to Fluke Biomedical.
Unpacking and Inspection Follow standard receiving practices upon receipt of the instrument. Check the shipping carton for damage. If damage is found, stop unpacking the instrument. Notify the carrier and ask for an agent to be present while the instrument is unpacked. There are no special unpacking instructions, but be careful not to damage the instrument when unpacking it. Inspect the instrument for physical damage such as bent or broken parts, dents, or scratches.
Technical Support For application support or answers to technical questions, either email [email protected] or call 1-800- 648-7952 or 1-425-446-6945.
Claims Our routine method of shipment is via common carrier, FOB origin. Upon delivery, if physical damage is found, retain all packing materials in their original condition and contact the carrier immediately to file a claim. If the instrument is delivered in good physical condition but does not operate within specifications, or if there are any other problems not caused by shipping damage, please contact Fluke Biomedical or your local sales representative.
Standard Terms and Conditions Refunds and Credits
Please note that only serialized products and their accessory items (i.e., products and items bearing a distinct serial number tag) are eligible for partial refund and/or credit. Nonserialized parts and accessory items (e.g., cables, carrying cases, auxiliary modules, etc.) are not eligible for return or refund. Only products returned within 90 days from the date of original purchase are eligible for refund/credit. In order to receive a partial refund/credit of a product purchase price on a serialized product, the product must not have been damaged by the customer or by the carrier chosen by the customer to return the goods, and the product must be returned complete (meaning with all manuals, cables, accessories, etc.) and in “as new” and resalable condition. Products not returned within 90 days of purchase, or products which are not in “as new” and resalable condition, are not eligible for credit return and will be returned to the customer. The Return Procedure (see below) must be followed to assure prompt refund/credit.
Restocking Charges
Products returned within 30 days of original purchase are subject to a minimum restocking fee of 15 %. Products returned in excess of 30 days after purchase, but prior to 90 days, are subject to a minimum restocking fee of 20 %. Additional charges for damage and/or missing parts and accessories will be applied to all returns.
Return Procedure
All items being returned (including all warranty-claim shipments) must be sent freight-prepaid to our factory location. When you return an instrument to Fluke Biomedical, we recommend using United Parcel Service, Federal Express, or Air Parcel Post. We also recommend that you insure your shipment for its actual replacement cost. Fluke Biomedical will not be responsible for lost shipments or instruments that are received in damaged condition due to improper packaging or handling.
Use the original carton and packaging material for shipment. If they are not available, we recommend the following guide for repackaging:
Use a double–walled carton of sufficient strength for the weight being shipped. Use heavy paper or cardboard to protect all instrument surfaces. Use nonabrasive material around all
projecting parts. Use at least four inches of tightly packed, industry-approved, shock-absorbent material around the
instrument. Returns for partial refund/credit:
Every product returned for refund/credit must be accompanied by a Return Material Authorization (RMA) number, obtained from our Order Entry Group at 1-800-648-7952 or 1-425-446-6945.
Repair and calibration:
To find the nearest service center, go to www.flukebiomedical.com/service or In the U.S.A.: Cleveland Calibration Lab Tel: 1-800-850-4606 Email: [email protected]
Everett Calibration Lab Tel: 1-888-99 FLUKE (1-888-993-5853) Email: [email protected] In Europe, Middle East, and Africa: Eindhoven Calibration Lab Tel: +31-402-675300 Email: [email protected] In Asia: Everett Calibration Lab Tel: +425-446-6945 Email: [email protected]
To ensure the accuracy of the Product is maintained at a high level, Fluke Biomedical recommends the product be calibrated at least once every 12 months. Calibration must be done by qualified personnel. Contact your local Fluke Biomedical representative for calibration.
Certification This instrument was thoroughly tested and inspected. It was found to meet Fluke Biomedical’s manufacturing specifications when it was shipped from the factory. Calibration measurements are traceable to the National Institute of Standards and Technology (NIST). Devices for which there are no NIST calibration standards are measured against in-house performance standards using accepted test procedures.
WARNING Unauthorized user modifications or application beyond the published specifications may result in electrical shock hazards or improper operation. Fluke Biomedical will not be responsible for any injuries sustained due to unauthorized equipment modifications.
Restrictions and Liabilities Information in this document is subject to change and does not represent a commitment by Fluke Biomedical. Changes made to the information in this document will be incorporated in new editions of the publication. No responsibility is assumed by Fluke Biomedical for the use or reliability of software or equipment that is not supplied by Fluke Biomedical, or by its affiliated dealers.
Manufacturing Location The ProSim™ 6/8 Vital Signs Simulator is manufactured at Fluke Biomedical, 6920 Seaway Blvd., Everett, WA, U.S.A.
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Table of Contents
Title Page
Introduction........................................................................................................ 1 Intended Use ...................................................................................................... 1 Safety Information ............................................................................................. 2 Symbols ............................................................................................................. 2 Unpack the Product............................................................................................ 3 Accessories ........................................................................................................ 3 Instrument Familiarization................................................................................. 5 How to Turn the Product On.............................................................................. 7 Pre-Defined Simulations.................................................................................... 7 ECG Function .................................................................................................... 10
How to Set the ECG Parameters.................................................................... 10 How to View the ECG Waveform................................................................. 12 How to Simulate an ECG Artifact ................................................................. 13 How to Simulate Arrhythmias....................................................................... 13
Supraventricular Arrhythmias ................................................................... 15 Premature Arrhythmias ............................................................................. 16 Ventricular Arrhythmias ........................................................................... 16 Conduction Arrhythmias ........................................................................... 17
Pacemaker Waveforms.................................................................................. 18 Advance Cardiac Life Support (ACLS) Waveforms (ProSim 8 only) .......... 19 ECG Performance Tests ................................................................................ 20
How to Set a Performance Wave .............................................................. 20 How to Set R Wave Detection Values (ProSim 8 only)............................ 21 How to Set QRS Detection Test Values (ProSim 8 only)......................... 22 How to Set Tall T Wave Rejection Test Values (ProSim 8 only)............. 23
Fetal Simulation (ProSim 8 only) ...................................................................... 24 How to Set Fetal Heart Values ...................................................................... 24 How to Simulate Intrauterine Pressure (IUP)................................................ 25
How to Set the Fetal Heart Rate Response ............................................... 27 How to Set the Intrauterine Contraction Simulation ................................. 27
Invasive Blood Pressure Simulation and Tests .................................................. 28 How to Set the Invasive Blood Pressure Variables ....................................... 28 How to Simulate Invasive Blood Pressure Tests........................................... 29
How to Simulate a Swan-Ganz Procedure ................................................ 30 How to Simulate a Cardiac Catheterization Procedure (ProSim 8 only) .. 31
How to Simulate Temperature ........................................................................... 34
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How to Simulate Respiration ............................................................................. 35 How to Simulate Cardiac Output....................................................................... 36
How to Set the Cardiac Output Waveform.................................................... 40 How to Set the Baseline Temperature ........................................................... 40 How to Set Injectate Temperature ................................................................. 40 How to Start a Cardiac Output Simulation.................................................... 40
Non-Invasive Blood Pressure Simulation and Tests.......................................... 40 How to Set the Non-Invasive Blood Pressure Variables ............................... 41 How to Do an NIBP Monitor Test................................................................. 44 How to Do a Pressure Leak Test ................................................................... 45 How to Do a Pressure Relief Test ................................................................. 47 How to Do a Pressure Source Test ................................................................ 48 How to Check a Manometer.......................................................................... 50
SpO2 Simulation................................................................................................ 51 How to Set the SpO2 Parameters .................................................................. 53 How to Simulate a Masimo Rainbow SpO2.................................................. 55 How to Perform an Oximeter Limits Test ..................................................... 55
Oxygen Limits Test................................................................................... 55 Pulse Rate Test.......................................................................................... 55 Pulse Amplitude/Perfusion Test................................................................ 56
Autosequences ................................................................................................... 56 How to View the Steps of an Autosequence ................................................. 58 How to Do an Autosequence ......................................................................... 59
How to Save and View Test Results (ProSim 8 only) ....................................... 59 How to Make an Operator ID........................................................................ 60 How to Make a Test ID ................................................................................. 61 How to Save Test Results.............................................................................. 62 How to View Test Results ............................................................................. 63 How to Print Test Results.............................................................................. 65 How to Delete Saved Data ............................................................................ 65
Setup Features.................................................................................................... 66 How to Set the Time and Date....................................................................... 66 How to Set the Backlight Intensity................................................................ 67 How to Set the Beeper ................................................................................... 67 How to Set the Pressure Units and IBP Sensitivity ....................................... 67 How to Set Battery Settings .......................................................................... 68 How to Set the Display Language ................................................................. 68
How to Control the Product Remotely............................................................... 69 Maintenance....................................................................................................... 69
How to Clean the Product.............................................................................. 70 Battery Maintenance...................................................................................... 70
How to Charge the Battery........................................................................ 70 Battery Removal........................................................................................ 71
General Specifications ....................................................................................... 72 Detailed Specifications ...................................................................................... 73
Normal-Sinus-Rhythm Waveform ................................................................ 73 Pacemaker Waveform ................................................................................... 73 Arrhythmia .................................................................................................... 73 ECG-Performance-Testing ............................................................................ 74 ECG Artifact.................................................................................................. 75 Fetal / Maternal-ECG (ProSim 8 only).......................................................... 75 Invasive Blood Pressure ................................................................................ 75 Respiration..................................................................................................... 75 Temperature................................................................................................... 76 Cardiac Output............................................................................................... 76
Contents (continued)
iii
Non-Invasive Blood Pressure ........................................................................ 76 SpO2 Simulations (optional) ......................................................................... 77 Pre-Defined Simulations ............................................................................... 77 Autosequences (default) ................................................................................ 77
Glossary ............................................................................................... A1 Introduction........................................................................................................ A1
ProSim™ 6/8 Users Manual
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v
List of Tables
Table Title Page
1. Simulation Types ................................................................................................... 1 2. Symbols.................................................................................................................. 2 3. Standard Accessories ............................................................................................. 3 4. Optional Accessories.............................................................................................. 4 5. Top-Panel Controls and Connections..................................................................... 5 6. Back, Front, and Side Panel Connections .............................................................. 6 7. Pre-Defined Patient Simulations ............................................................................ 8 8. ECG Wave Groups................................................................................................. 11 9. ECG Lead Amplitudes ........................................................................................... 12 10. Arrhythmias by Wave Group ................................................................................. 13 11. Pacemaker Waveforms........................................................................................... 18 12. Performance Wave Rates ....................................................................................... 21 13. Cardiac Output Waveforms.................................................................................... 40 14. Autosequences........................................................................................................ 56
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vii
List of Figures
Figure Title Page
1. Top-Panel Controls and Connections..................................................................... 5 2. Back, Front, and Side Panel Connections .............................................................. 6 3. Power-Up Screen ................................................................................................... 7 4. Home Screen .......................................................................................................... 7 5. ECG Connections................................................................................................... 10 6. ECG Screen............................................................................................................ 10 7. ECG Graph Screen ................................................................................................. 12 8. ECG NSR Adult Screen ......................................................................................... 13 9. Performance Wave Screen ..................................................................................... 20 10. R-Wave Detection Screen ...................................................................................... 21 11. QRS Detection Screen............................................................................................ 22 12. Tall T Wave Rejection Screen ............................................................................... 24 13. Fetal ECG Screen................................................................................................... 24 14. Fetal Monitor Connections for Intrauterine Pressure Simulation........................... 26 15. Intrauterine Pressure Contractions Screen ............................................................. 26 16. Fetal ECG Intrauterine Pressure Screen................................................................. 27 17. Invasive Blood Pressure Screen ............................................................................. 28 18. IBP with Chambers Screen .................................................................................... 29 19. Invasive Blood Pressure Connections .................................................................... 30 20. Initial Swan-Ganz Procedure Simulation Screen ................................................... 30 21. Insert Step in Swan-Ganz Procedure Simulation ................................................... 31 22. Aortic Valve Catheterization Simulation Screen ................................................... 32 23. Pulmonary Valve Catheterization Simulation Screen ............................................ 33 24. Mitral Valve Catheterization Simulation Screen.................................................... 33 25. Temperature Simulation Connection ..................................................................... 34 26. Respiration Screen ................................................................................................. 35 27. Cardiac Output Injectate Cable Modification ........................................................ 38 28. Cardiac Output Connections .................................................................................. 39 29. Cardiac Output Screen ........................................................................................... 39 30. Non-Invasive Blood Pressure Test Connections .................................................... 41 31. Adjustments for Adult Blood Pressure Cuff Mandrel............................................ 41 32. Neonatal Blood Pressure Cuff Mandrel ................................................................. 42 33. Non-Invasive Blood Pressure Screen..................................................................... 42 34. Blood Pressure Measurement Graph...................................................................... 44 35. NIBP Summary Screen .......................................................................................... 45 36. Pressure Leak Test Connections ............................................................................ 45
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37. Leak Test Screen .................................................................................................... 46 38. Leak Test Pumping Screen..................................................................................... 46 39. Example Leak Test Result Screen.......................................................................... 47 40. Pressure Relief Valve Test Results Screen............................................................. 48 41. Pressure Source Connection................................................................................... 49 42. Pressure Source Pumping Screen........................................................................... 49 43. Manometer Connections ........................................................................................ 50 44. Manometer Screen ................................................................................................. 50 45. SpO2 Simulation Screen ........................................................................................ 51 46. SpO2 Simulation Connections ............................................................................... 51 47. SpO2 Sensor Placement ......................................................................................... 52 48. Magnetic Holder for SpO2 Artificial Finger.......................................................... 53 49. Autosequence Start Screen..................................................................................... 58 50. Autosequence Step Screen ..................................................................................... 59 51. Memory Organization of Test Results ................................................................... 60 52. Operator ID Screen ................................................................................................ 60 53. Change Operator ID Screen ................................................................................... 61 54. Save Screen ............................................................................................................ 62 55. Observed Results Screen........................................................................................ 63 56. Saving Screen......................................................................................................... 63 57. Test ID Screen........................................................................................................ 64 58. Test Results Screen ................................................................................................ 64 59. Test Results Data Screen........................................................................................ 64 60. Setup Screen........................................................................................................... 66 61. External Battery Charging Connections................................................................. 71 62. Battery Removal..................................................................................................... 72
1
Introduction The Fluke Biomedical ProSim™ 6 and ProSim™ 8 Vital Signs Simulators (hereafter the Product) are full-featured, compact, portable simulators, used to measure the performance of patient monitors. The Fluke Biomedical ProSim™ 8 is shown in all illustrations.
The Product simulates:
• ECG Functions • Respiration • Invasive and Non-Invasive Blood Pressure • Temperature • Cardiac Output • SpO2
When the term simulation is used in connection with ECG, respiration, temperature, IBP, NIBP, cardiac output, or SpO2, the simulation type shown in Table 1 is used in this Product.
Table 1. Simulation Types
Parameter Simulation Type
ECG Electrical
Respiration Electrical
Temperature Electrical
IBP Electrical
NIBP Pneumatic
Cardiac Output Electrical
SpO2 Light Emission
Intended Use The Product is intended to be used to test and verify the basic operation of patient monitoring devices or systems used to monitor various physiological parameters of a patient, including ECG, Respiration, Invasive blood pressure, Non-invasive blood pressure, Temperature, Cardiac output, and SpO2.
The intended user is a trained biomedical equipment technician who performs periodic preventative maintenance checks on patient monitors in service. Users can be associated with hospitals, clinics, original equipment manufacturers and independent service companies that repair and service medical equipment. The end user is an individual, trained in medical instrumentation technology.
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This Product is intended to be used in the laboratory environment, outside of the patient care area, and is not intended for use on patients, or to test devices while connected to patients. This Product is not intended to be used to calibrate medical equipment and not intended for over the counter use.
Safety Information In this manual, a Warning identifies hazardous conditions and actions that could cause bodily harm or death. A Caution identifies conditions and actions that could damage the Product, the equipment under test, or cause permanent loss of data.
Warnings To prevent personal injury, use the Product only as specified, or the protection supplied by the Product can be compromised.
To prevent possible electrical shock, fire, or personal injury:
• Do not use and disable the Product if it is damaged.
• The battery door must be closed and locked before you operate the Product.
• Remove all probes, test leads, and accessories that are not necessary for the measurement.
• Do not use the Product around explosive gas, vapor, or in damp or wet environments.
• Do not use the Product if it operates incorrectly.
• Do not connect the Product to a patient or equipment connected to a patient. The Product is intended for equipment evaluation only and should never be used in diagnostics, treatment, or any other capacity where the Product would come in contact with a patient.
• Read all safety Information before you use the Product.
• Examine the case before you use the Product. Look for cracks or missing plastic. Carefully look at the insulation around the terminals.
• Carefully read all instructions.
Symbols Table 2 describes symbols used in association with the Product.
Table 2. Symbols
Symbol Description Symbol Description
Risk of danger. Important information. See manual.
Hazardous voltage. Risk of electric shock.
This Product contains a Lithium-ion battery. Do not mix with solid waste stream. Spent batteries should be disposed of by a qualified recycler or hazardous materials handler per local regulations. Contact your authorized Fluke Service Center for recycling information.
Do not dispose of this Product as unsorted municipal waste. Go to Fluke’s website for recycling information.
Magnetic Field. Conforms to European Union directives.
Vital Signs Simulator Unpack the Product
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Unpack the Product Carefully unpack all items from the box and check that you have these items:
• ProSim™ 8 or ProSim™ 6 • Getting Started Manual • Users Manual CD • Carrying Case • Power Cord • AC/DC Power Supply
• USB Cable • IBP Cable (unterminated) • NIBP Cuff Mandrel set (adult and
neonate) • NIBP Cuff Adapters • Ansur Demostration Disk
After you unpack and inspect the Product, fully charge the battery before the first use. Afterwards, charge the battery when the Product shows the low battery message. See the How to Maintain the Battery section in this manual.
Accessories Available Product accessories are shown in Tables 3 and 4.
Table 3. Standard Accessories
Item Fluke Biomedical Part Number
ProSim™ 6/8 Getting Started Manual 3980667
ProSim™ 6/8 Users Manual CD 3980671
AC/DC Power Supply 2184298
US 2201455
Schuko 2201437
UK 2201428
Japan 2201419
Australia 2201443
AC Power Cord
Brazil 1671807
USB Cable 1626219
IBP Cable, unterminated 2392173
Carrying Case 3987170
End blocks (2 required) 2392370 Set of NIBP Cuff Mandrels
Space blocks (3 required) 2392381
Neonatal Cuff Mandrel 2392328
Set of NIBP Cuff Adapters 2391882
Ansur Demonstration CD-ROM 2795488
ProSim 6/8 Users Manual
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Table 4. Optional Accessories
Item Fluke Biomedical Part Number
SpO2 Simulation Finger Module with cable 3985658
SpO2 Masimo RAINBOW Simulation cable 3987181
Battery pack 3938110
NIBP Test 500 mL rigid chamber 3890640
Simulation Cables: IBP Temperature
See your Fluke Biomedical Distributor
Cardiac Output Interface Box 2392199
Upgrade kit to ProSim™ 8 3987196
USB Wireless Dongle 3341333
Mini-DIN to DIN IBP Adapter 3408564
Vital Signs Simulator Instrument Familiarization
5
Instrument Familiarization Table 5 is a list of Product top-panel controls and connections shown in Figure 1.
F1 F2 F3 F4 F5
Top
14
13 1011 98
7
6
5
4
2
3
15
16
18
17
1
12
glh034.eps
Figure 1. Top-Panel Controls and Connections
Table 5. Top-Panel Controls and Connections
Item Name Description
1 ECG Posts Connection posts for Device Under Test (DUT) ECG leads.
2 ECG Function Accesses the ECG waveforms (adult, pediatric, and arrhythmias), and ECG test functions (performance waves, QRS detection, Tall T wave rejection, and R wave detection).
3 NIBP Button Accesses the Non-Invasive Blood Pressure (NIBP) functions.
4 Special Functions Accesses the temperature, respiration, cardiac output, fetal simulation, autosequences, and view memory functions.
5 SETUP Button Accesses the setup controls.
6 IBP Button Accesses the Invasive Blood Pressure (IBP) functions.
7 Navigation Buttons Cursor control buttons for navigating menus and lists.
8 Enter Button Sets the highlighted function.
9 Backlight Button Turns the display backlight on and off.
10 Power Button Turns the Product on and off.
11 SpO2 Button Accesses the SpO2 functions.
12 Function Softkeys
Keys F1 through F5 are used to select from a number of selections that appear in the LCD display above each function softkey.
13 LCD Display Color display.
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Table 5. Top-Panel Controls and Connections (cont.)
Item Name Description
14 SpO2 Connector Connector to the SpO2 simulation accessory.
15 IBP Channel 1 Connector Connector to an IBP input of the patient monitor.
16 Cardiac Output Connector Connector to the Cardiac input of the patient monitor.
17 IBP Channel 2 Connector Connector to the IBP input of the patient monitor.
18 Temperature Connector Connector to the Temperature input of the patient monitor.
Front Right
Back
1
4
7 8
5 62 3
glh035.eps
Figure 2. Back, Front, and Side Panel Connections
Table 6. Back, Front, and Side Panel Connections
Item Name Description
1 AC/DC Supply Connector Input jack for the DC output of the AC/DC supply connector.
2 Battery Charge LED Battery charges when LED shows red. Green shows battery charge is complete.
3 Battery Latch Locks the battery pack into the Product. Push down to remove the battery pack.
4 Mini B USB Device Port Used to connect to a PC for remote control or download test results data to a PC.
5 USB A Controller Port For external keyboard, barcode reader, or printer.
6 ECG BNC Connector High-level output of ECG signal.
7 Air Port Connector Pressure port for NIBP cuff and monitor.
8 Magnetic Holder for SpO2 Simulated Finger Module
Holds the simulated finger module in two orientations.
Vital Signs Simulator How to Turn the Product On
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How to Turn the Product On Push on the front panel to turn the Product on. The screen shown in Figure 3 shows the power-up screen.
glh002.bmp
Figure 3. Power-Up Screen
When the self test is complete and no errors are sensed, the home screen in Figure 4 shows in the display.
glh001.bmp
Figure 4. Home Screen
From the home screen, a number of pre-defined patient simulations can be used to set all the simulation functions at one time. See Pre-Defined Simulations to learn more on how to use simulations. Waveform and ECG rate parameters are set through the ECG function. See the ECG Function section to learn more on how to set these variables. The respiration rate (Resp Rate), temperature parameter, cardiac output, and fetal simulation are set through the special functions menu. The two Invasive Blood Pressure (IBP) channels are set through the IBP function. The Non-Invasive Blood Pressure variables are set through the NIBP function. See the Blood Pressure Simulations and Tests section to learn more on how to set IBP and NIBP variables. The SpO2 variable is set through the SpO2 function. See the SpO2 Simulation section to learn more on how to set this variable.
Pre-Defined Simulations The pre-defined simulations are set through the softkeys along the bottom of the home screen. See Figure 4. There are seven factory pre-defined simulations: normal, hypertensive, hypotensive, tachycardic, bradycardic, heart attack, and asystole. A More softkey shows in the display for more simulations. Table 7 lists the parameter values for each pre-defined simulation.
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Table 7. Pre-Defined Patient Simulations
Simulation Name Parameter Pre-Set Value
Wave Form NSR (Adult)
ECG Rate 60 bpm
Respiration Rate 20 bpm
Temperature 37.0 °C
IBP Channel 1 120/80 mmHg (Art)
IBP Channel 2 25/10 mmHg (PA)
NIBP 120/80 (93) mmHg
Normal
SpO2 100%
Wave Form NSR (Adult)
ECG Rate 120 bpm
Respiration Rate 30 bpm
Temperature 38.0 °C
IBP Channel 1 200/150 mmHg (Art)
IBP Channel 2 40/20 mmHg (LV)
NIBP 200/150 (166) mmHg
Hypertensive
SpO2 90%
Wave Form NSR (Adult)
ECG Rate 40 bpm
Respiration Rate 15 bpm
Temperature 36.0 °C
IBP Channel 1 80/50 mmHg (Art)
IBP Channel 2 25/0 mmHg (RA)
NIBP 50/20 (30) mmHg
Hypotensive
SpO2 97%
Wave Form Mono V Tach
ECG Rate 180 bpm
Respiration Rate 50 bpm
Temperature 40.0 °C
IBP Channel 1 80/50 mmHg (Art)
IBP Channel 2 25/0 mmHg (RV)
NIBP 80/50 (60) mmHg
Tachycardia
SpO2 88%
Vital Signs Simulator Pre-Defined Simulations
9
Table 7. Pre-Defined Patient Simulations (cont.)
Simulation Name Parameter Pre-Set Value
Wave Form NSR (Adult)
ECG Rate 30 bpm
Respiration Rate 15 bpm
Temperature 35.0 °C
IBP Channel 1 100/65 mmHg (Art)
IBP Channel 2 100/0 mmHg (LV)
NIBP 100/65 (167) mmHg
Bradycardic
SpO2 85%
Wave Form Atrial Fibrillation (Coarse)
ECG Rate No bpm
Respiration Rate 70 bpm
Temperature 34.0 °C
IBP Channel 1 200/150 mmHg (Art)
IBP Channel 2 40/20 mmHg (LV)
NIBP 200/150 (167) mmHg
Heart Attack
SpO2 94%
Wave Form Asystole
ECG Rate 0 bpm
Respiration Rate 0 bpm
Temperature 33.0 °C
IBP Channel 1 0 mmHg
IBP Channel 2 0 mmHg
NIBP 0/0 mmHg
Asystole
SpO2 50%
After you set one of the pre-defined simulations, you can change the parameters of one or all of the vital signs. Changes are not kept in the Product. The pre-defined simulation parameters can not be changed through the front panel.
There are seven custom pre-defined simulations in the Product. To set a custom simulation:
1. From the Home screen, push the More softkey.
2. Push the Custom softkey.
Four custom simulation names show above the first four softkeys. The names are Custom1, Custom2, Custom3, and Custom4. To show the next three names, push the More softkey.
3. Push the softkey for a custom pre-defined simulation.
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All the vital sign simulation parameters are set to the values contained in the pre-defined simulation.
You can customize the seven factory simulations and seven custom simulations through the Ansur functionality.
ECG Function The Product simulates normal heart signals (ECG) as well as heart signals for a variety of arrhythmias. Heart rate (beats per minute), signal amplitude, and ST segment elevation are all controlled by the Product through the user interface. Artifacts can also be simulated.
To measure the ECG performance of a monitor, connect the Product to the monitor as shown in Figure 5. A maximum of ten ECG leads can be connected to Product.
ProSim 8
PatientMonitor
ECGCable
glh030.eps
Figure 5. ECG Connections
How to Set the ECG Parameters Whenever the Product is turned on, the display shows the defaults for heart rate (60 BPM) with a patient type of Adult. Although not shown on the initial display, the signal amplitude is 1 mV. To set any of the ECG parameters, push . The ECG screen shown in Figure 6 shows in the display.
glh004.bmp
Figure 6. ECG Screen
Vital Signs Simulator ECG Function
11
To change the ECG waveform:
1. Push or to move the highlight to the Wave Group value.
2. Push .
3. Push or to move the highlight to a waveform group name. Table 8 is a list of the wave groups available in the Product.
Table 8. ECG Wave Groups
Wave group
NSR (Adult) Adult Normal Sinus Rhythm
NSR (Pediatric) Child Normal Sinus Rhythm
Performance
R-Wave Detection (ProSim 8 only)
QRS Detection (ProSim 8 only)
Tall T Wave Rejection (ProSim 8 only)
Special waveforms for monitor tests. See the ECG Tests section.
Supraventricular
Premature
Ventricular
Conduction
TV Paced
ACLS (ProSim 8 only)
Arrhythmia waveforms. See the How to Simulate Arrhythmias section.
4. When the waveform group value is highlighted, push .
To change the heart rate:
1. Push or to move the highlight in the display to the Heart Rate value.
2. Push .
3. Push or to adjust the heart rate. Each push of a key moves the heart rate one beat in the direction of the key pushed. The ProSim 8 simulates a heart rate of 10 to 360 beats/minute (BPM) set in 1 BPM intervals. The ProSim 6 simulates a heart rate of 30 to 360 beats/minute (BPM) set in 10 BPM intervals.
4. Push to set the heart rate and go back to the ECG screen.
To change the axis:
1. Push or to move the highlight to the Axis value.
2. Push .
3. Push or to highlight Intermediate, Horizontal, or Vertical.
4. Push .
To set the ST Deviation:
1. Push or to move the highlight to the ST Deviation value.
2. Push .
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3. Push or to adjust the deviation. Each push of a key moves the deviation 0.05 or 0.1 mV in the direction of the key pushed. The deviation range is ±0.80 mV
Note
When the ST Deviation value is set to 0.00 mV, the value in ECG screen will show as Off.
4. Push to set the deviation and go back to the ECG screen.
To set the ECG signal amplitude:
1. Push or to move the highlight in the display to the Amplitude value.
2. Push .
3. Push or to adjust the amplitude. Each push of a key increases or decreases the amplitude 0.05 mV between 0.05 and 0.50 mV and 0.25 mV above 0.50 mV to 5.00 mV in the direction of the key pushed.
4. Push to set the signal amplitude and go back to the ECG screen.
Table 9 shows the percentage of the signal amplitude value that is put on each ECG lead.
Table 9. ECG Lead Amplitudes
Waveform I II III V1 V2 V3 V4 V5 V6
Performance [1] 70 % 100 % 30 % 100 % 100 % 100 % 100 % 100 % 100 %
Normal Sinus 70 % 100 % 30 % 24 % 48 % 100 % 120 % 112 % 80 %
Normal Sinus, Horizontal Axis
100 % 30 % -70 % 20 % 40 % 70 % 100 % 80 % 50 %
Normal Sinus, Vertical Axis
30 % 130 % 100 % 20 % 30 % 40 % 60 % 80 % 100 %
[1] Includes R-Wave Detection, QRS Detection, and Tall T-Wave Rejection waves.
How to View the ECG Waveform As you adjust the ECG signal, you can see the signal in the display. To see the ECG signal, from the ECG screen, push the Graph softkey. The graph screen in Figure 7 shows in the display.
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Figure 7. ECG Graph Screen
The ECG signal is shown in the display in real time.
Push the Back softkey to go back to the ECG screen.
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How to Simulate an ECG Artifact The Product simulates a number of different ECG artifacts that can change the accuracy of an ECG indication. ECG artifact simulations, which can be added to an ECG wave, include line-frequency artifacts of 60 Hz (U.S. lines) and 50 Hz (European lines), as well as artifacts for muscle movement, wandering baseline, and respiration.
All simulated ECG signals can have an artifact added to the ECG signal. To add an artifact:
1. Push to show the ECG screen in Figure 8 in the display.
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Figure 8. ECG NSR Adult Screen
2. Push or to highlight the Artifact Type value.
3. Push or to highlight 50 Hz, 60 Hz, Muscular, Baseline Wander, or Respiration.
4. Push to enable the artifact and go back to the ECG screen.
To change the size of the artifact:
1. From the ECG screen, push or to highlight the Artifact Size value.
2. Push or to highlight 100%, 50%, or 25%.
3. Push to set the artifact size and go back to the ECG screen.
The artifact signal can be made to one ECG lead or all leads. To change which lead the artifact is on:
1. From the ECG screen, push or to highlight the Artifact Lead value.
2. Push or to highlight RA, LL, LA, V1 – V6, or All Leads in the lead list.
3. Push to set the artifact lead and go back to the ECG screen.
How to Simulate Arrhythmias All arrhythmia simulations are grouped into related wave groups. These arrhythmia wave groups are Supraventricular, Premature, Ventricular, Conduction, TV Paced, and ACLS. Table 10 shows all the arrhythmias the Product can simulate and identifies in which wave group they can be found. The table also identifies which model can simulate the arrhythmia.
Table 10. Arrhythmias by Wave Group
Arrhythmia Wave Group Available in
Asynchronous 75 BPM TV Paced ProSim 6 and 8
Asystole ACLS, Ventricular ProSim 6 and 8
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Table 10. Arrhythmias by Wave Group (cont.)
Arrhythmia Wave Group Available in
Atr-Vent Sequential TV Paced ProSim 6 and 8
Atrial Fibrillation Supraventricular ProSim 6 and 8
Atrial Flutter Supraventricular ProSim 8 only
Atrial PAC Premature ProSim 6 and 8
Atrial Tach Supraventricular ProSim 8 only
Atrial 80 BPM TV Paced ProSim 6 and 8
Bigeminy Ventricular ProSim 6 and 8
Bradycardia ACLS ProSim 8 only
Demand Freq Sinus TV Paced ProSim 6 and 8
Demand Occ Sinus TV Paced ProSim 6 and 8
Freq Multi-focal PVCs Ventricular ProSim 8 only
Ischemic Chest Pain ACLS ProSim 8 only
Lt Bndl Branch Block Conduction ProSim 8 only
MIs with LBBB ACLS ProSim 8 only
MIs with RBBB ACLS ProSim 8 only
Missed Beat at 80 BPM Supraventricular ProSim 8 only
Missed Beat at 120 BPM Supraventricular ProSim 8 only
Mono V Tach Ventricular ProSim 6 and 8
Multi-focal PVCs Premature ProSim 6 and 8
Myocardial Infarctions ACLS ProSim 8 only
Narrow Complex Tach ACLS ProSim 8 only
Nodal PNC Premature ProSim 8 only
Nodal Rhythm Supraventricular ProSim 8 only
Non-Capture TV Paced ProSim 6 and 8
Non-Function TV Paced ProSim 6 and 8
Paroxysmal ATach Supraventricular ProSim 8 only
Poly V Tach Ventricular ProSim 6 and 8
Poly V Tach (unstable) ACLS ProSim 8 only
Pulseless Vent Tach ACLS ProSim 8 only
Pulseless Elect Tach ACLS ProSim 8 only
PVCs Ventricular ProSim 8 only
PVC1 Left Vent Premature ProSim 8 only
PVC1 LV Early Premature ProSim 8 only
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Table 10. Arrhythmias by Wave Group (cont.)
Arrhythmia Wave Group Available in
PVC1 LV R on T Premature ProSim 8 only
PVC2 Right Vent Premature ProSim 8 only
PVC2 RV Early Premature ProSim 8 only
PVC2 RV R on T Premature ProSim 8 only
Rt Bndl Branch Block Conduction ProSim 6 and 8
Run of PVCs Ventricular ProSim 8 only
Sinus Arrhythmia Supraventricular ProSim 6 and 8
Stable Tachycardias ACLS ProSim 8 only
Supra VTach Supraventricular ProSim 8 only
Trigeminy Ventricular ProSim 8 only
Unstable Tachycardias ACLS ProSim 8 only
Ventricular Fibrillation Ventricular ProSim 6 and 8
Wide Complex Tach ACLS ProSim 8 only
1st Deg AV Block Conduction ProSim 8 only
2nd Deg AV Block T1 Conduction ProSim 6 and 8
2nd Deg AV Block T2 Conduction ProSim 8 only
3rd Deg AV Block Conduction ProSim 8 only
Supraventricular Arrhythmias To set a supraventricular arrhythmia:
1. From the ECG screen, push or to highlight the Wave Group value.
2. Push .
3. Push or to highlight Supraventricular in the wave group list.
4. Push .
5. Push or to highlight the Waveform value.
6. Push .
7. Push or to highlight a waveform in the list.
8. Push to set the arrhythmia waveform and go back to the ECG: Supraventricular screen.
The amplitude of all supraventricular arrhythmia waveforms can be adjusted. See the How to Set the ECG Parameters section above. ECG signal artifacts can also be added to each arrhythmia signal. See the How to Simulate an ECG Artifact section above.
The atrial fibrillation arrhythmia has one variable not available on the other supraventricular arrhythmias. The type variable can be set to coarse or fine. To change the type variable with the atrial fibrillation waveform set:
1. Push or to highlight the Type value.
2. Push .
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3. Push or to highlight Coarse or Fine from the list.
4. Push to set the arrhythmia type and go back to the ECG: Supraventricular screen.
Premature Arrhythmias The premature wave group arrhythmias simulate premature contraction of muscle at different nodes of the heart. To do a premature arrhythmia:
1. From the ECG screen, push or to highlight the Wave Group value.
2. Push .
3. Push or to highlight Premature in the wave group list.
4. Push .
5. Push or to highlight the Waveform value.
6. Push .
7. Push or to highlight a waveform in the list.
8. Push to set the arrhythmia waveform and go back to the ECG: Supraventricular screen.
The amplitude of all premature arrhythmia waveforms can be adjusted. See the How to Set the ECG Parameters section above. ECG signal artifacts can also be added to each arrhythmia signal. See the How to Simulate an ECG Artifact section above.
Ventricular Arrhythmias Ventricular arrhythmias are arrhythmias in the lower chambers of the heart, or ventricles. To do a ventricular arrhythmia:
1. From the ECG screen, push or to highlight the Wave Group value.
2. Push .
3. Push or to highlight Ventricular in the wave group list.
4. Push .
5. Push or to highlight the Waveform value.
6. Push .
7. Push or to highlight a waveform in the list.
8. Push to set the arrhythmia waveform and go back to the ECG: Ventricular screen.
The amplitude of all ventricular arrhythmia waveforms can be adjusted. See the How to Set the ECG Parameters section above. ECG signal artifacts can also be added to each arrhythmia signal. See the How to Simulate an ECG Artifact section above.
The ventricular fibrillation and poly V tach arrhythmias have a variable not available on the other ventricular arrhythmias. To change the type variable for the ventricular fibrillation and poly v tach waveform set:
1. Push or to highlight the Type value.
2. Push .
3. Push or to highlight Coarse or Fine from the list.
4. Push to set the arrhythmia type and go back to the ECG: Ventricular screen.
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The mono v tach arrhythmia has a heart rate variable. To change the heart rate:
1. Push or to highlight the Heart Rate value.
2. Push .
3. Push or to adjust the heart rate. Each push of a key moves the heart rate one beat in the direction of the key pushed. A heart rate of 120 to 300 beats/minute (BPM) can be set in 5 BPM intervals for this arrhythmia.
4. When the heart rate is set, push to set the arrhythmia heart rate and go back to the ECG: Ventricular screen.
The PVCs arrhythmia has a rate variable to set the number of PVCs in a minute. To change the rate of PVCs:
1. Push or to highlight the Rate value.
2. Push .
3. Push or to highlight 6/min, 12/min, or 24/min in the list.
4. Push to set the arrhythmia rate and go back to the ECG: Ventricular screen.
The Run of PVCs arrhythmia has a number variable to set the number of PVCs in a run. To change the number of PVCs in a run:
1. Push or to highlight the Number value.
2. Push .
3. Push or to highlight 2 PVCs, 5 PVCs, or 11 PVCs.
4. Push to set the arrhythmia number and go back to the ECG: Ventricular screen.
Conduction Arrhythmias Conduction arrhythmias are caused when conduction of electrical impulses are stopped or blocked from their usual pathways around the heart. To simulate a conduction arrhythmia:
1. From the ECG screen, push or to highlight the Wave Group value.
2. Push .
3. Push or to highlight Conduction in the wave group list.
4. Push .
5. Push or to highlight the Waveform value.
6. Push .
7. Push or to highlight a waveform in the list.
8. Push to set the arrhythmia waveform and go back to the ECG: Conduction screen.
The amplitude of all conduction arrhythmia waveforms can be adjusted. See the How to Set the ECG Parameters section above. ECG signal artifacts can also be added to each arrhythmia signal. See the How to Simulate an ECG Artifact section above.
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Pacemaker Waveforms The Product can simulate ECG waveforms with a number of artificial-pacemaker conditions. Table 11 shows the simulations in the waveform list of the Product with a description of each.
Table 11. Pacemaker Waveforms
Pacemaker Waveform Label Waveform Description
Atrial 80 bpm Atrial pacemaker wave at 80 BPM, with a pacer pulse at the start of each P wave.
Asynchronous 75 bpm Asynchronous pacemaker wave with continuous ventricular-paced beats (75 BPM) and no P waves
Demand Freq Sinus A “demand” pacemaker wave with frequent sinus beats (forty normal beats followed by twenty ventricular-paced beats, repeated)
Demand Occ Sinus A “demand” pacemaker wave with occasional sinus beats (twenty normal beats followed by forty ventricular-paced beats, repeated)
Atr-Vent Sequential AV-sequential-pacemaker wave with continuous paced beats, each with an atrial pulse and a P wave followed by a ventricular-paced pulse and QRS response
Non-Capture Ventricular-paced beats, where one out of ten beats has no heart response.
Non-Function Continuous pacer pulses at 75 BPM with no heart response.
To select a pacemaker waveform simulation:
1. From the ECG screen, push or to highlight the Wave Group value.
2. Push .
3. Push or to highlight TV Paced in the wave group list.
4. Push .
5. Push or to highlight the Waveform value.
6. Push .
7. Push or to highlight a waveform in the list.
8. Push to set the arrhythmia waveform and go back to the ECG: TV Paced screen.
The amplitude of all TV Paced waveforms can be adjusted. See the How to Set the ECG Parameters section above. ECG signal artifacts can also be added to each arrhythmia signal. See the How to Simulate an ECG Artifact section above.
TV-Paced waveforms include the applicable pacer pulses. The pacer pulses can be changed through the front panel. All but the Atrial 80 bpm waveform have ventricle pacemaker variables that can be changed. The Atrial 80 bpm has an atrial pacemaker value. The Atr-Vent Sequential waveform has an atrial pacemaker value and a ventricle pacemaker value. To change the pacemaker values push the Atrial Settings or Vent. Settings softkey.
You can change the amplitude, width, and polarity of the pacemaker signal. To change the amplitude:
1. Push or to highlight the Amplitude value.
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2. Push .
3. Push or to highlight an amplitude value in the list. Below is a list of the pacemaker amplitude values.
0 mV 16 mV
2 mV 18 mV
4 mV 20 mV
6 mV 50 mV
8 mV 100 mV
10 mV 200 mV
12 mV 500 mV
14 mV 700 mV
4. Push to set the amplitude and go back to the TV Paced Settings screen.
To change the width value:
1. Push or to highlight the Width value.
2. Push .
3. Push or to highlight 0.1, 0.2, 0.5, 1.0, 1.5, or 2.0 mV in the list.
4. Push to set the width and go back to the TV Paced Settings screen.
To change the polarity:
1. Push or to highlight the Polarity value.
2. Push .
3. Push or to highlight + or - in the list.
4. Push to set the polarity and go back to the TV Paced Settings screen.
Push the Back softkey to go back to the ECG: TV Paced screen.
Advance Cardiac Life Support (ACLS) Waveforms (ProSim 8 only) The Product can simulate Advanced Cardiac Life Support (ACLS) waveforms.
To simulate an ACLS waveform:
1. From the ECG screen, push or to highlight the Wave Group value.
2. Push .
3. Push or to highlight ACLS in the wave group list.
4. Push .
5. Push or to highlight the Waveform value.
6. Push .
7. Push or to highlight a waveform in the list.
8. Push to set the waveform and go back to the ECG: ACLS screen.
The amplitude of all ACLS waveforms can be adjusted. See the How to Set the ECG Parameters section above. ECG signal artifacts can also be added to each arrhythmia signal. See the How to Simulate an ECG Artifact section above.
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ECG Performance Tests As well as physiological waveforms, the Product can supply signals to measure the performance of an ECG monitor. A set of performance waveforms are used to measure the frequency response (high and low), sensitivity, gain drift, internal calibration, stylus damping, paper speed, linearity, and sweep speed of an ECG monitor. Three more Product functions are used to measure R wave detection, QRS detection, and tall T wave rejection of an ECG monitor.
How to Set a Performance Wave The waveforms in the performance wave group are sine, square, triangle, and pulse.
Note
When a performance wave is set on the Product, outputs for respiration, blood pressure, and temperature are disabled.
The four waveforms used for ECG performance tests are, sine, square, pulse, and triangle. The rate and amplitude of these waveforms are adjustable to preconfigured values. To output a performance wave:
1. Push to show the ECG screen in the display.
2. Push or to highlight the Wave Group value.
3. Push .
4. Push or to highlight the Performance value in the wave group list.
5. Push to show the ECG: Performance screen in Figure 9 in the display.
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Figure 9. Performance Wave Screen
To change the waveform:
1. Push or to highlight the Waveform value.
2. Push .
3. Push or to highlight Square, Sine, Triangle, or Pulse in the list.
4. Push to set the performance waveform and go back to the ECG: Performance screen.
All waveforms have the same two variables: Rate and Amplitude.
To change the rate:
1. Push or to highlight the Rate value.
2. Push .
3. Push or to highlight a value in the rate list. Table 12 lists the rates for each type of wave.
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Table 12. Performance Wave Rates
Performance Wave Rates
Square and Triangle 0.125, 2.0, and 2.5 Hz
Sine 0.05, 0.5, 1, 2, 5, 10, 25, 30, 40, 50, 60, 100, and 150 Hz
Pulse 30 and 60 bpm
4. Push to set the rate and go back to the ECG: Performance screen.
To change the amplitude:
1. Push or to highlight the Amplitude value.
2. Push .
3. Push or to adjust the amplitude. Each push of a key increases or decreases the amplitude 0.05 mV between 0.05 and 1.00 mV and 0.25 mV above 1 mV to 5.00 mV in the direction of the key pushed.
4. Push to set the rate and go back to the ECG: Performance screen.
How to Set R Wave Detection Values (ProSim 8 only) To sense a heartbeat, a monitor looks for R waves. The sensed R wave is used to calculate heart rate and other analysis. You adjust the R wave to find the range of values a heart monitor can sense a heart beat. The R wave is a simple triangular pulse.
To output a signal for an R Wave detection test:
1. Push to show the ECG screen in the display.
2. Push or to highlight the Wave Group value.
3. Push .
4. Push or to highlight the R Wave Detection value in the wave group list.
5. Push to show the ECG: R Wave Detection screen in Figure 10 in the display.
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Figure 10. R-Wave Detection Screen
The rate, amplitude, and width of the R wave can be changed. To change the rate:
1. Push or to highlight the Rate value.
2. Push .
3. Push or to highlight 30, 60, 90, 120, 200, or 250 bpm in the list.
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4. Push to set the rate and go back to the ECG: R Wave Detection screen.
To change the R wave amplitude:
1. Push or to highlight the Amplitude value.
2. Push .
3. Push or to adjust the amplitude. Each push of a key increases or decreases the amplitude in the direction of the key pushed. The Product simulates a heart signal amplitude of 0.05 to 0.25 mV by 0.05 mV intervals and 0.05 to 5.00 mV that is set in 0.25 mV intervals.
4. When the amplitude is set, push to enter the value and go back to the R Wave Detection screen.
To change the width of the R Wave:
1. Push or to highlight the Width value.
2. Push .
3. Push or to adjust the width. Each push of a key increases or decreases the width 20 ms for each key push when the value is 20 ms or above and 2 ms when the value is 20 ms or less. The Product simulates an R Wave width of 8 to 200 ms.
4. When the amplitude is set, push to enter the value and go back to the R Wave Detection screen.
How to Set QRS Detection Test Values (ProSim 8 only) The QRS Detection wave group supplies a signal that you can adjust the width of the QT interval. This QRS Detection wave includes the R and S waves with relative amplitudes as specified in EC-13. The R wave is 0.875 of the waveform amplitude and the S wave is negative at 0.125 of the waveform amplitude. The R wave up slope is 0.4375 of the waveform width. The R wave down slope is 0.5 of the waveform width. The S wave up slope is 0.0625 of the waveform width.
To generate a signal for an QRS detection test:
1. Push to show the ECG screen in the display.
2. Push or to highlight the Wave Group value.
3. Push .
4. Push or to highlight the QRS Detection value in the wave group list.
5. Push to show the ECG: QRS Detection screen in Figure 11 in the display.
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Figure 11. QRS Detection Screen
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The rate, amplitude, and width of the QRS wave can be changed.
To change the rate:
1. Push or to highlight the Rate value.
2. Push .
3. Push or to highlight 30, 60, 90, 120, 200, or 250 bpm in the list.
4. Push to set the rate and go back to the ECG: QRS Detection screen.
To change the QRS Wave amplitude:
1. Push or to highlight the Amplitude value.
2. Push .
3. Push or to adjust the amplitude. Each push of a key increases or decreases the amplitude in the direction of the key pushed. The Product simulates a heart signal amplitude of 0.05 to 0.25 mV by 0.05 mV intervals and 0.50 to 5.00 mV that is set in 0.25 mV intervals.
4. Push to set the amplitude and go back to the ECG: QRS Detection screen.
To change the width of the QT interval:
1. Push or to highlight the Width value.
5. Push .
6. Push or to adjust the width. Each push of a key increases or decreases the width 10 ms for each key push when the value is 20 ms or above and 2 ms when the value is 20 ms or less. The Product simulates a QT width of 8 to 200 ms.
7. When the width is set, push to enter the value and go back to the ECG: QRS Detection screen.
How to Set Tall T Wave Rejection Test Values (ProSim 8 only) An ECG monitor must sense and reject a large T wave when it calculates the heart rate. Use the Tall T Wave Rejection waveform for this test. This wave includes the QRS wave per EC-13 with a 100 ms width and QT interval of 350 ms. The T wave has a sinusoidal shape, 180 ms wide, and can be adjusted in amplitude to 0 to 150 % of the overall waveform amplitude. The rate is set at 80 bpm. To output a tall T wave signal:
1. Push to show the ECG screen in the display.
2. Push or to highlight the Wave Group value.
3. Push .
4. Push or to highlight the Tall T Wave Rejection value in the wave group list.
5. Push to show the ECG: Tall T Wave Rejection in Figure 12 in the display.
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glh022.bmp
Figure 12. Tall T Wave Rejection Screen
The amplitude of the T Wave can be changed. To change the amplitude:
1. Push or to highlight the Amplitude value.
2. Push .
3. Push or to increase or decrease the T Wave amplitude. The amplitude is set as a percentage of the voltage on the reference lead. The range is 0 to 150 % in 10 % steps.
4. Push to enter the value and go back to the ECG: Tall T Wave Rejection screen.
Fetal Simulation (ProSim 8 only) The Product simulates a mixed fetal and maternal electrocardiogram (ECG) that occurs during labor, as well as a selection of pressure waveforms made by uterine contractions. The contraction period can be changed. There is also a manual contraction.
Note
The maternal heart rate is always a normal sinus rhythm at 80 beats/minute.
How to Set Fetal Heart Values The Product simulates the fetal/maternal ECG on its regular ECG leads. The maternal signal is a P-QRS-T wave at half the set ECG amplitude. The fetal signal is a narrow R wave at full amplitude. Fetal and maternal signals are summed to make a composite signal.
To do a fetal simulation:
1. Push .
2. Push , , , or to highlight Fetal Simulation and then push to show the Fetal ECG screen in the display. See Figure 13.
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Figure 13. Fetal ECG Screen
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Push the softkey labeled Back to go back to the Special Functions screen.
To change the fetal heart rate:
1. Push or to highlight the Fetal HR value.
2. Push .
3. Push or to change the heart rate value in 1 bpm steps between 60 and 240 bpm.
Note
When you hold down the direction key, the step size will change to 10 bpm until the key is released.
4. Push to set the heart rate and go back to the Fetal ECG screen.
To change the amplitude of the fetal waveform:
1. Push or to highlight the Amplitude value.
2. Push or to adjust the amplitude. Each push of a key increases or decreases the amplitude in the direction of the key pushed. The Product simulates a fetal heart signal amplitude of 0.05 to 0.25 mV by 0.05 mV intervals and 0.50 to 5.00 mV that is set in 0.25 mV intervals..
3. Push to set the amplitude and go back to the Fetal ECG screen.
How to Simulate Intrauterine Pressure (IUP) The simulated intrauterine-pressure (IUP) waveform shows a measurement read by an intra-amniotic catheter connected to a pressure transducer. The Product simulates the IUP on IBP channel 1, with a 5 or 40 μV/V/mmHg sensitivity (as has been setup for blood pressure).
The Product sends waveforms to simulate intrauterine pressure during a contraction of the uterus in childbirth. Each IUP wave goes for 90 seconds with a bellshaped pressure curve that increases from zero to 90 mmHg and goes back to zero. In an IUP-wave simulation, the fetal heart rate (which always begins at 140 BPM, regardless of the fetal ECG rate.) changes with the blood pressure. The fetal heart rate and blood pressure shows in the display.
The IUP period is adjustable to four preconfigured values: a manually started contraction, and contractions that start at 2, 3, or 5 minute intervals.
To do an Intrauterine pressure simulation, connect the fetal monitor to the Product as shown in Figure 14.
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ProSim 8
Fetal Monitor
IntrauterineBlood Pressure
Input
Fetal ECGInput
Maternal ThighReference Plate Fetal Scalp
Electrode
JumperWires
BP Cable
IBP Channel 1
glh058.eps
Figure 14. Fetal Monitor Connections for Intrauterine Pressure Simulation
To simulate intrauterine pressure contractions push the IUP Contraction softkey to show the Fetal ECG: IUP screen in the display. See Figure 15.
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Figure 15. Intrauterine Pressure Contractions Screen
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How to Set the Fetal Heart Rate Response The Product simulates four types of preconfigured waveforms for a periodic fetal heart rate that is interactive with uterine contractions: variable deceleration; early deceleration; late deceleration; or acceleration:
With variable deceleration, the change in fetal heart rate lags the change in intrauterine pressure by 30 seconds. The fetal heart rate starts at 140 BPM, slows to 100 BPM, and then goes back to 140 BPM.
With early deceleration, the fetal heart rate follows the intrauterine pressure (no lag). The fetal heart rate starts at 140 BPM, slows to 100 BPM at intrauterine-pressure peak, and then goes back to 140 BPM as the IUP falls back to zero.
With late deceleration, the change in fetal heart rate starts when IUP pressure is at its peak and lags the change in intrauterine pressure by 45 seconds. The fetal heart rate starts at 140 BPM, slows to 100 BPM, and then goes back to 140 BPM.
With acceleration, the change in fetal heart rate lags the change in intrauterine pressure by 30 seconds. The fetal heart rate starts at 140 BPM, increases to 175 BPM, and then goes back 140 BPM.
To set the fetal heart rate response:
1. Push or to highlight the HR Response value.
2. Push .
3. Push or to highlight Early Deceleration, Variable Deceleration, Late Deceleration, or Acceleration.
4. Push to set the response value and go back to the Fetal ECG: IUP screen.
How to Set the Intrauterine Contraction Simulation The IUP (Intrauterine Pressure) period is adjustable to four preconfigured values. These are contractions that start manually or at 2, 3, or 5 minute intervals.
To set the contractions:
1. Push or to highlight the Contraction value.
2. Push .
3. Push or to highlight Manual Start, 2, 3, or 5 minutes.
4. Push to set the contraction value and go back to the Fetal ECG: IUP screen.
5. To start a contraction, push the Start softkey. The screen below shows in the display and updates with real-time simulation data. The time until the contraction ends is also shown in the display. See Figure 16.
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Figure 16. Fetal ECG Intrauterine Pressure Screen
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If the contraction value is set to Manual Start, only one contraction cycle is simulated.
The timer shows the time until the contraction ends and the subsequent contraction starts.
Push the Stop softkey to stop contractions and go back to the Fetal ECG: IUP screen.
Invasive Blood Pressure Simulation and Tests The Product simulates blood pressure for Invasive blood pressure monitors. Each blood pressure variable can be set through the front-panel controls. The Product also simulations Swan-Ganz and cardiac catheterization procedures.
How to Set the Invasive Blood Pressure Variables The Product can simulate two invasive blood pressure transducers at one time. The blood pressure variables are set separately for each channel. To set these variables, push to show the IBP screen in Figure 17 in the display.
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Figure 17. Invasive Blood Pressure Screen
To set the chamber:
1. Push or to highlight the Chamber value on channel 1 or channel 2.
2. Push .
3. Push or to highlight a value in the chamber list. Below is a list of chamber values in the Product.
Static Right Ventricle
Arterial Pulmonary Artery
Radial Artery PA Wedge
Left Ventricle Right Atrium (CVP)
Left Atrium
4. Push to set the chamber and go back to the IBP screen.
You must first zero the patient monitor when you connect to a new IBP transducer or patient simulator. To set a channel to 0 mmHg and Static chamber, push the Zero Channel 1 or Zero Channel 2 softkey. After you zero the patient monitor, do the zero function on the patient monitor.
To set the pressure:
1. Push or to highlight the Pressure value on channel 1 or channel 2.
2. Push .
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Systolic and diastolic pressures are set separately.
Note
If the chamber is set to static, only one pressure is set.
3. Push or to highlight the systolic or diastolic pressure value.
4. Push or to increase or decrease the pressure value in 1 mmHg steps. The range is -10 to +300 mmHg.
Note
When you hold down the direction key, the step size will change to 10 mmHg until the key is released.
5. Push to set the pressure and go back to the IBP screen.
When the Chamber parameter is set to a value other than Static, the artifact parameter is added to the display as shown in Figure 18.
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Figure 18. IBP with Chambers Screen
To set the artifact:
Note
Artifact value is not available when the chamber value is set to static.
1. Push or to highlight the Artifact value on channel 1 or channel 2.
2. Push .
3. Push or to highlight 5% or 10% if the chamber parameter is set to Arterial, Radial Artery, or Left Ventricle. Highlight 5 mmHg or 10 mmHg for all other chamber values. Highlight Off to turn off the artifact function
Note
The artifact values in the list can be in percent (%) or in mmHg. These units are set by the chamber value.
4. Push to set the artifact value and go back to the IBP screen.
The IBP screen reappears in the display with the new artifact selection.
How to Simulate Invasive Blood Pressure Tests The Product can simulate pressures that occur during a Swan-Ganz or Cardiac Catheterization procedure. Figure 19 shows a monitor connected to the two IBP channel jacks on the Product.
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ProSim 8PatientMonitor
IBP Cables
glh028.eps
Figure 19. Invasive Blood Pressure Connections
How to Simulate a Swan-Ganz Procedure To simulate IBP during a Swan-Ganz procedure:
1. Push the Tests softkey in the IBP screen.
2. Push or to highlight Swan-Ganz – Channel 1 or Swan-Ganz – Channel 2.
3. Push . The details and steps in the procedure shown in Figure 20 are shown in the display.
glh012.bmp
Figure 20. Initial Swan-Ganz Procedure Simulation Screen
You can do the Swan-Ganz procedure manually or automatically.
To step through the procedure manually, push the Manual softkey. Each procedure step is shown in the display. To move to the subsequent step push the Next softkey.
After the first step, you push the Previous softkey to go back a step. You stop the procedure when you push the Stop softkey.
To do the steps automatically, push the Start Automatic softkey. The display in Figure 21 shows the Inserted (Right Atrium) step for the Swan-Ganz procedure.
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glh014.bmp
Figure 21. Insert Step in Swan-Ganz Procedure Simulation
There is a 15 second period between steps. The remaining time for each step shows in the right part of the display. You can push the Pause softkey to stop the countdown to the subsequent step while the Product continues the patient simulation for that step. Continue replaces Pause when the procedure step is paused. Push Continue to continue the step.
You can go back a step when you push the Previous softkey. The Product simulates that step for a full 15 seconds before it does the subsequent step. When you push the Previous softkey while paused, the Product goes back a step, but stays paused and sets the time to 15 seconds.
When you push the Stop softkey, the procedure simulation is stopped and the initial test screen shown in Figure 20 shows in the display.
How to Simulate a Cardiac Catheterization Procedure (ProSim 8 only)
Note
The Cardiac Catheterization procedure is only available in the ProSim 8. The Product simulates blood pressure measurements on both sides of a heart valve. The pressure difference, or gradient across the valve is used to determine heart valve condition.
To simulate a Cardiac Catheterization procedure:
1. Push the Tests softkey in the IBP screen.
2. Push or to highlight Cardiac Catheterization.
3. Push . The valve selection is shown in the display.
To change the valve value:
1. Push .
2. Push or to highlight Aortic, Pulmonary, or Mitral.
3. Push to go back to the IBP: Cardiac Catheterization screen.
To start the procedure simulation:
1. Push the Start softkey.
All the procedure steps are done manually.
2. Push the Insert softkey for the next step.
3. You simulate an increase and decrease of simulated pressure when you push the Increase Pressure or Decrease Pressure softkeys.
4. Push the Pullback softkey to simulate the pressures when the catheter is pulled back.
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Push the Stop softkey to stop the procedure and go back to the IBP: Cardiac Catheterization screen.
Aortic Valve Catheterization Simulation The aortic valve controls flow from the left ventricle (LV) to the aorta (atrial pressure) and prevents flow in the reverse direction. Both IBP channels are set the Arterial 120/80. IBP channel 1 stays at arterial 120/80 for reference throughout the simulation.
1. Push the Insert softkey to simulate the insertion of IBP channel 2 catheter into the left ventricle at 120/0. Figure 22 shows the screen for the aortic valve catheterization simulation.
glh054.bmp
Figure 22. Aortic Valve Catheterization Simulation Screen
For a normal valve, when the heart beat starts, the LV pressure increases to 80 mmHg. Then, as the valve opens, both pressures increase to the systolic peak. Next, the pressures fall until the valve opens. The LV pressure goes back down, but the arterial stays at 80 mmHg.
2. Push the Increase Pressure or Decrease Pressure to simulate a bad aortic valve. There are six pressure values between 120 and 180 mmHg. Each push of the increase softkey sets the left ventricle pressure to 126 (+5 %), 132 (+10 %), 138 (+15 %), 144 (+20 %), and 180 (+50 %). Each push of the decrease softkey sets the pressure down from 180 to 120 mmHg with the same pressure steps.
3. Push the Pullback softkey to simulate the pull back of the IBP channel 2 catheter to the left ventricle.
Pulmonary Valve Catheterization Simulation The pulmonary valve controls flow from the right ventricle (RV) to the pulmonary artery (PA) and prevents flow in the reverse direction. Both IBP channels are set to PA 25/10. IBP channel 1 stays at PA 25/10 for reference throughout the simulation.
1. Push the Insert softkey to simulate the insertion of the IBP channel 2 catheter into the right ventricle at 25/0.
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glh055.bmp
Figure 23. Pulmonary Valve Catheterization Simulation Screen
For a normal valve, when the heart beat starts, the RV pressure increases to 10 mmHg. Then, as the valve opens, both pressures increase to the systolic peak. Next, the pressures fall until the valve opens. The RV pressure goes back down, but the pulmonary artery stays at 10 mmHg.
2. Push the Increase Pressure or Decrease Pressure to simulate a bad pulmonary valve. There are six pressure values between 25 and 38 mmHg. Each push of the increase softkey sets the left ventricle pressure to 26 (+5 %), 28 (+10 %), 29 (+15 %), 30 (+20 %), and 38 (+50 %). Each push of the decrease softkey sets the pressure down from 38 to 25 mmHg with the same pressure steps.
3. Push the Pullback softkey to simulate the pull back of the IBP channel 2 catheter to the right ventricle.
Mitral Valve Cahteterization Simulation The mitral valve controls flow from the left atrium (LA) to the left ventricle (LV) and prevents flow in the reverse direction. A mitral valve test is done indirectly with pressure measurements in the pulmonary artery (PA). There are two measurements: normal and wedged. A wedged measurement is done with a inflated ballon (PAW) in the pulmonary artery to measure the back pressure from the left ventricle through the left atrium and the lungs. At the start of the procedure, IBP channel 1 is set to LV 120/0 and channel 2 is set to pulmonary artery (PA) 25/10/. IBP channel 1 stays at LV 120/0 for reference throughout the simulation.
1. Push the Insert softkey to simulate a change in IBP channel 2 catheter pressure to the pulmonary artery wedge pressure (PAW) of 10/2.
glh056.bmp
Figure 24. Mitral Valve Catheterization Simulation Screen
For a normal valve, the PAW pressure stays low because there is little back pressure from the left ventricle through the left atrium and the lungs.
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2. Push the Increase Pressure or Decrease Pressure to simulate a bad mitral valve. There are six pressure values between 10/2 and 36/24 mmHg. Each push of the increase softkey sets the left ventricle pressure to 26/18, 29/19, 31/21, 34/22, and 36/24. Each push of the decrease softkey sets the pressure down from 36/24 to 10/2 mmHg with the same pressure steps.
3. Push the Pullback softkey to simulate the pulmonary artery wedge (PAW) balloon deflation. This changes IBP channel 2 back to the pulmonary artery.
How to Simulate Temperature Temperatures simulated by the Product are compatible with Yellow Springs, Inc. (YSI) Series 400 and 700 probes. The type of cable connected to the temperature jack sets the type of temperature probe simulated. Connect the temperature input of the UUT to the Temperature jack as shown in Figure 25.
ProSim 8PatientMonitor
TemperatureCable
glh038.eps
Figure 25. Temperature Simulation Connection
To set the simulated temperature:
1. Push .
2. Push , , , or to highlight the Temperature selection then push to show the set temperature in the display.
3. Push .
4. Push or to change the temperature in 0.5 °C steps between 30.0 and 42.0 °C.
Note
When you hold down the direction key, the step size will change to 1.0 °C until the key is released.
5. Push to set the temperature and go back to the Temperature screen.
Vital Signs Simulator How to Simulate Respiration
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How to Simulate Respiration Respiration variables are set through the special functions. To set respiration:
1. Push .
2. Push , , , or to highlight Respiration.
3. Push . The Respiration screen in Figure 26, shows in the display.
glh013.bmp
Figure 26. Respiration Screen
You can choose between a normal or ventilated respiration waveform and change the respiration rate. The respiration signal can be set to the left arm (LA) or left leg (LL) ECG lead. The baseline impedance between the leads and the amplitude of impedance variation (respiration amplitude) are set though the front panel as well. To set respiration between normal and ventilated:
1. Push or to highlight the Wave value.
2. Push .
3. Push or to highlight Normal or Ventilated.
4. Push to set the wave and go back to the Respiration screen.
To set the respiration rate:
1. Push or to highlight the Rate value.
2. Push .
3. Push or to increase or decrease the rate of respiration in 1 brpm steps between 10 and 150 brpm.
4. Push to set the respiration rate and go back to the Respiration screen.
To set the respiration ratio:
1. Push or to highlight the Ratio value.
2. Push .
3. Push or to highlight 1:1, 1:2, 1:3, 1:4, or 1:5.
4. Push to set the respiration ratio and go back to the Respiration screen.
To set the respiration amplitude:
1. Push or to highlight the Amplitude value.
2. Push .
3. Push or to change the amplitude in 0.05 Ω steps between 0.00 and 5.00 Ω.
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4. Push to set the amplitude and go back to the Respiration screen.
To set the baseline resistance:
1. Push or to highlight the Baseline value.
2. Push .
3. Push or to highlight 500, 1000, 1500, or 2000 Ω in the list.
4. Push to set the baseline impedance and go back to the Respiration screen. The baseline impedance is kept in memory and is non-volatile.
Note
Baseline value is kept in memory and is non-volatile.
To set the respiration lead:
1. Push or to highlight the Respiration lead.
2. Push .
3. Push or to highlight LA or LL in the list.
4. Push to set the respiration lead and go back to the Respiration screen. The respiration lead is kept in memory and is non-volatile.
Note
Respiration lead value is kept in memory and is non-volatile.
How to Set Apnea Simulation You can simulate an apnea period manually or for a specified time period. To control an apnea period manually, push the Continuous Apnea softkey from the respiration screen. The display shows a timer which shows the time since the apnea period started. The respiration simulation is stopped when the Stop softkey is pushed.
To do a timed apnea period:
1. Push the Timed Apnea softkey from the respiration screen.
2. Push or to highlight 12, 22, or 32 seconds.
3. Push .
The display shows a timer that counts down the apnea period. When the timer counts down to zero, the apnea period ends and the display shows the respiration screen. Push the Stop softkey to abort the apnea function.
How to Simulate Cardiac Output The Cardiac Output function electronically simulates the dynamic temperature changes in the blood of the patient during a thermal dilution cardiac output measurement.
Thermal dilution cardiac output measurements are given by the heat interchange between the blood of the patient and a known volume of chilled saline put into the heart. Cardiac output is expressed in liters per minute (L/min) and ranges between 3 L/min and 7 L/min in normal adults.
Current cardiac output measurement devices can make sure you get the most accurate measurements. This includes an average of a series of measurements to prevent variations because of artifacts. This rejects measurements because of clinician technique or the underlying cardiovascular disease in a patient.
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Note
Cardiac output measurement devices that use different techniques (such as Fick dye injection, Doppler ultrasonography and bioimpedance) are not addressed or intended for this Product.
To simulate cardiac output, a CI-3 module/jack is necessary and connects to the cardiac output jack of the Product. This module has connections for the cardiac output measurement under test and simulates the injectate temperature (IT) thermistors at 0 °C or 24 °C. Of the two connectors on the CI-3 module/cable, the smaller 3-pin connector is for catheter blood temperature (BT) and is standard on most monitors.
Note
This 3-pin catheter BT connector is compatible with the standard Baxter (Edwards) BT catheter and equivalent catheters available from other manufacturers such as Viggo-SpectraMed and Abbott (Sorenson).
The larger 4-pin connector supplies the simulated injectate temperature. The 10-turn 100 kΩ potentiometer enables adjustment of the injectate temperature to 0 or 24 °C.
Although this 100 kΩ range of resistance has proven adequate to simulate the 0 or 24 °C temperature for most brands of cardiac output measurement devices, the 4-pin IT thermistors connector is not standard on all monitors. A general function connector that you can connect to the device under test (DUT) injectate cable is also supplied.
Figure 27 shows the general-purpose connector assembly. Note that the injectate temperature thermistor has to be cut off the EUT cable to install the general-purpose connector.
Note
A DUT cardiac output cable changed for this test must not be used in a clinical application.
If the DUT cardiac output cable includes an interconnection (or plug-in) for the injectate temperature bath probe assembly, change the plug-in cable only.
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Blood temperature (BT) connector
Injectate temperature (IT) thermistor connector
Injectate temperature (IT) 10-turn potentiometer
CI-3 module/cable
2
14
3
Pin1
Pin3
Crimp tubeThermistor end of cable
ASSEMBLY of the GENERAL PURPOSE CONNECTOR
Viewed from the top of the C1-3
PIN1
FUNCTIONINJECTATE THERMISTOR CONNECTION A
Injectate temperature (IT) thermistor connector
INJECTATE THERMISTOR CONNECTION B
2 NO CONNECTION
4 NO CONNECTION
3
Solder wires to pins 1 and 3
eic224.eps
Figure 27. Cardiac Output Injectate Cable Modification
Note
Fluke Biomedical offers optional adapter cables to connect the Product to specified brands of cardiac output measurement devices.
• To examine Hewlett Packard Merlin systems, a cardiac output adapter and a temperature adapter are necessary.
• A special adapter is necessary for Gould/SpectraMed Models SP1445 and SP1465 cardiac output devices.
Contact Fluke Biomedical for availability, price, and part number.
For cardiac output simulation, use the supplied CI-3 module/cable to connect the Product to the DUT. (see Figure 28). If necessary, use the general-purpose connector.
Vital Signs Simulator How to Simulate Cardiac Output
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6
60705040
ProSim 8
PatientMonitor
Cardiac OutputAdapter
BloodTemperatureConnection
InjectateTemperatureConnection
glh057.eps
Figure 28. Cardiac Output Connections
Setup the DUT for the simulated parameters that follow:
• Catheter Size: 7 F • Injectate Volume: 10 cc • Computational Constant: 0.542 or 0.595, based on the injectate temperature.
To set the Product for a cardiac output test:
1. Push .
2. Push , , , or to highlight Cardiac Output and then push to show the cardiac output parameters in the display. See Figure 29.
glh017.bmp
Figure 29. Cardiac Output Screen
Push the softkey labeled Back to go back to the Special Functions screen,
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How to Set the Cardiac Output Waveform To set the cardiac output waveform:
1. In the Cardiac Output screen, use or to highlight the wave parameter.
2. Push .
3. Push or to highlight a waveform name in the list of waveforms.
Table 13 shows the cardiac output waveforms for the Product.
Table 13. Cardiac Output Waveforms
Waveform Description
2.5 L/min Normal waveform with accuracy of 2.5 L/min
5.0 L/min Normal waveform with accuracy of 5.0 L/min
10.0 L/min Normal waveform with accuracy of 10.0 L/min
Interrupted Injectable Interrupted injection waveform
LR Shunt Left to right ventricular shunt
Calibrated Pulse Calibrated square wave pulse
4. Push to set the wave and go back to the Cardiac Output screen.
How to Set the Baseline Temperature To set the baseline temperature:
1. In the cardiac output screen, if not already highlighted, use or to highlight the baseline temperature value.
2. Push .
3. Push or to highlight 36 °C, 37 °C, or 38 °C.
4. Push to set the baseline temperature and go back to the Cardiac Output screen.
How to Set Injectate Temperature To set the injectate temperature:
1. In the cardiac output screen, use or to highlight the injectate temperature value.
2. Push .
3. Push or to highlight 0 °C or 24 °C.
4. Push to set the temperature and go back to the Cardiac Output screen.
As you change the injectate temperature, the calibration coefficient necessary for the monitor is shown in the display.
How to Start a Cardiac Output Simulation After you set the parameters for a cardiac output simulation, push the Start softkey. The simulation completes automatically. To stop the simulation, push the Stop softkey.
Non-Invasive Blood Pressure Simulation and Tests The Product simulates blood pressure for Non-Invasive blood pressure monitors. Each blood pressure variable can be set through the front-panel controls. The Product also does leak, pressure source, and pressure relief tests. The manometer function sets the Product to measure static pressure and shows the pressure in the display.
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How to Set the Non-Invasive Blood Pressure Variables For non-invasive blood pressure tests, connect the Product to the BP cuff and monitor as shown in Figure 30.
ProSim 8
PatientMonitor
Mandrel
Dual hose system: connect Cuff Adapter to hose marked “Sense”. If both hoses are unmarked, connect Cuff Adapter to either hose.
Blood Pressure CuffWraps around mandrel.
Must be connected closer to the cuff than monitor.
glh031.eps
Figure 30. Non-Invasive Blood Pressure Test Connections
There are two blood pressure cuff mandrels that are used with the Product: Adult and Neonatal. Figure 31 shows the parts of an adult mandrel and how to assemble it for different sizes.
Large Adult Use 2 end blocks and3 spacer blocks
Use 2 end blocks and2 spacer blocks
Use 2 end blocks and1 spacer blocks
Use 2 end blocks andno spacer blocks
Adult Cuff Mandrel Sizes
Adult
Small Adult
Child
fcv011.eps
Figure 31. Adjustments for Adult Blood Pressure Cuff Mandrel
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Figure 32 shows the neonatal blood pressure cuff mandrel.
LargeMedium
Small
fcv012.eps
Figure 32. Neonatal Blood Pressure Cuff Mandrel
To set the blood pressure simulation, push to show the NIBP screen in Figure 33 in the display.
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Figure 33. Non-Invasive Blood Pressure Screen
Pressure, heart rate, pulse volume, brand, and wave are set through the front-panel controls to simulate different patient conditions. Arrhythmia waveforms are also simulated in the NIBP simulation (set through ECG). To set the Blood Pressure:
1. Push or to highlight the Pressure variable.
2. Push .
Systolic and diastolic pressures are set separately.
3. Push or to highlight the systolic or diastolic pressure value.
4. Push or to increase or decrease the pressure value in 1 mmHg steps.
Note
When you hold down the direction key, the step size will change to 10 mmHg until the key is released.
5. Push to set the pressure and go back to the NIBP screen.
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Note
Heart Rate may not be shown in the NIBP screen if an arrhythmia or performance waveform is set.
To set the heart rate:
1. Push or to highlight the Heart Rate variable.
2. Push .
3. Push or to increase or decrease the heart rate in 1 bpm steps. The range is 30 to 240 bpm.
Note
When you hold down the direction key, the step size will change to 10 bpm until the key is released.
4. Push to set the heart rate and go back to the NIBP screen.
Note
Arrhythmia may show in the display instead of Heart Rate when an arrhythmia or performance waveform is set under the ECG function. The Mono VTach waveform is the one exception. You can only change the heart beat to normal sinus rhythm in the NIBP screen.
To set the heart beat waveform to normal sinus rhythm:
1. Push or to highlight the Arrhythmia variable.
2. Push .
3. Push or to increase or decrease the heart rate.
4. Push to set the heart rate and go back to the NIBP screen.
To set the pulse volume:
1. Push or to highlight the Pulse Volume variable.
2. Push .
3. Push or to increase or decrease the pulse volume in 0.05 mL steps. The pulse volume range is 0.10 to 1.25 mL.
4. Push to set the pulse volume and go back to the NIBP screen.
You can set the wave variable to Adult or Neonatal simulation. When set, the pulse volume is set to the default for that simulation: 1.0 ml for Adult, 0.5 ml for Neonatal. Afterwards, the pulse volume can be changed with its own control (see above). To set the wave variable:
1. Push or to highlight the Wave variable.
2. Push .
3. Push or to highlight Adult or Neonatal.
4. Push to set the wave and go back to the NIBP screen.
When the NIBP monitor starts the blood pressure measurement cycle, the Product keeps the measured parameters of the measurement cycle. If the NIBP screen is shown in the display when the measurement cycle starts, a graph of pressure versus time shows in the display. See Figure 34.
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glh005.bmp
Figure 34. Blood Pressure Measurement Graph
Note
The Summary and Graph softkeys show in the NIBP screen after you do an NIBP simulation.
To see the measured parameters of the last blood pressure measurement cycle, push the Summary softkey in the NIBP screen. To see the graph of the last NIBP simulation, push the Graph softkey in the NIBP screen,
How to Do an NIBP Monitor Test To do an accuracy test on an NIBP monitor:
1. Connect the NIBP monitor to the Product as shown in Figure 36.
2. Start an NIBP pressure cycle on the monitor. Refer to the monitor manual as necessary. After you start the blood pressure measurement cycle:
• The blood pressure cuff inflates around the mandrel.
• The Product starts the peripheral pulse simulation and shows the blood pressure measurement graph in the display.
Note
The graph shows in the display automatically only when the blood pressure measurement cycle starts when the NIBP screen shows in the display.
• The Product starts blood pressure simulation when the pressure is 10 mmHg. Heart beat simulation starts when the pressure equals the diastolic pressure set into the Product.
• The Product stops the simulation when the pressure is 2 mmHg or below.
• The NIBP monitor interprets and shows the measured blood pressure values and heart rate when the test stops.
3. Push the Summary softkey to show the blood pressure measurements in Figure 35 in the display.
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glh053.bmp
Figure 35. NIBP Summary Screen
4. Compare the NIBP monitor values with the target values shown in the Product display.
How to Do a Pressure Leak Test The leak test measures leaks in a non-invasive blood pressure monitor, the hoses connected to the monitor, and the pressure cuff.
Note
Before you do a pressure leak test on a monitor, do the pressure leak test without the monitor to identify the leak rate of the Product. Use this leak rate to offset the rate of the full system with the monitor connected.
Note
Put the NIBP monitor in “calibrate” or “service” mode to close the vent valve, so the Product can inflate the pneumatic system. Refer to the service manual for the NIBP monitor.
Connect the Product to the monitor and cuff as shown in Figure 36.
ProSim 8
PatientMonitor
Mandrel
Dual hose system: connect Cuff Adapter to hose marked “Sense”. If both hoses are unmarked, connect Cuff Adapter to either hose.
Blood Pressure CuffWraps around mandrel.
Must be connected closer to the cuff than monitor.
glh008.bmp
Figure 36. Pressure Leak Test Connections
ProSim 6/8 Users Manual
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Note
If the NIBP device has an internal system leak test or one that vents the cuff inflation pneumatic circuit to the atmosphere when idle, do not use the Leak Test. Rather, do a Manometer check to test for internal system leaks. Refer to the NIBP monitor operators manual for the recommended test protocol.
To perform a leak test:
1. Push to show the NIBP screen.
2. Push the Tests softkey.
3. Push or to highlight Leak Test.
4. Push to show the NIBP: Leak Test screen in Figure 37 in the display.
glh024.bmp
Figure 37. Leak Test Screen
The default target pressure is 300 mmHg. The target pressure can be set between 20 and 400 mmHg. To change the target pressure, push or to increase or decrease the pressure value in 1 mmHg steps.
Note
When you hold down the direction key, the step size will change to 10 mmHg until the key is released.
5. Push the Start softkey to start the leak test.
The Product pressurizes the pneumatic system to the target pressure. While the Product pumps air into the pneumatic system, the pressure and a graph of the pressure is shown in the display. See Figure 38.
glh006.bmp
Figure 38. Leak Test Pumping Screen
Vital Signs Simulator Non-Invasive Blood Pressure Simulation and Tests
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The pump stops when the measured pressure is the same as the target pressure. The Product waits for a time to let the pressure to become stable. Then the Product starts to measure and monitor the pressure for the test period.
When the test is done, the test results are shown in the display. An example pressure test result is shown in Figure 39.
glh007.bmp
Figure 39. Example Leak Test Result Screen
To set how long the test will run:
1. Push the Test Duration softkey.
2. Push or to adjust the time between 30 seconds and 5 minutes in 30 second steps. The default time is 1 minute.
3. Push to set the test duration and go back to the NIBP: Leak Test screen.
How to Do a Pressure Relief Test The pressure relief test pressurizes a pneumatic system until the Product senses a drop in pressure, as occurs when the relief valve opens. Or the test stops if the pressure gets to the target pressure and no relief is sensed.
Note
Put the NIBP monitor in “calibrate” or “service” mode to close the vent valve, so the Product can inflate the pneumatic system. Refer to the service manual for the NIBP monitor.
To test the relief valve:
1. From the NIBP screen, push the Tests softkey.
2. Push or to highlight Pressure Relief Test.
3. Push .
4. Push or to increase or decrease the target pressure between 100 and 400 mmHg in 1 mmHg steps.
Note
When you hold down the direction key, the step size will change to 10 mmHg until the key is released.
5. Push the Start softkey to begin the test.
The Product pressurizes the pneumatic system to the target pressure with the pressure measurement and a graph of the pressure shown in the display. See Figure 38. When the Product senses the pressure valve has opened, the test stops and the results are shown in the display. See Figure 40. It is recommended you do three pressure relief tests in case the relief valve is intermittent.
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If there is no drop in pressure and the pressure climbs to the target pressure, the pump stops and Not Tripped shows in the display.
Note
Some NIPB monitors do not let you access a “Service” mode. If you can not close the vent valve, the system can not be pressurized by an external pump. It is possible to start a blood pressure measurement with the monitor (this closes the valve), then start the Pressure Relief tests, so that two pumps inflate the system. The results can change, but the monitor usually opens a relief valve at some high pressure.
glh008.bmp
Figure 40. Pressure Relief Valve Test Results Screen
See the How to Save Test Results section to learn more on how to save your test results data.
How to Do a Pressure Source Test The pressure source test is used to pressurize a pneumatic system while it measures the pressure. This can be used for static calibration of non-invasive blood pressure measurement systems, sphygmomanometer checks, and other devices that measure pressure.
To do a pressure source test:
1. Connect the pressure port to pressure system as shown in Figure 41.
Vital Signs Simulator Non-Invasive Blood Pressure Simulation and Tests
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ProSim 8
MandrelBlood Pressure Cuff
Blood PressureGauge
Wraps around mandrel.
glh051.eps
Figure 41. Pressure Source Connection
2. From the NIBP screen, push the Tests softkey.
3. Push or to highlight Pressure Source.
4. Push .
5. Push or to increase or decrease the target pressure between 20 and 400 mmHg in 1 mmHg steps.
Note
When you hold down the direction key, the step size will change to 10 mmHg until the key is released.
6. Push the Start softkey to begin the test.
The Product pressurizes the pneumatic system to the target pressure. While the Product pumps air into the pneumatic system, the pressure measurement and a graph of the pressure is shown in the display. See Figure 42.
glh010.bmp
Figure 42. Pressure Source Pumping Screen
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Push the Stop softkey to stop the test. This will cause a Vent softkey to show in the display. The pressure will remain at the level it was when the Stop softkey was pushed. Either push the Vent softkey to vent the pressure system or change the pressure and push the Start softkey to do another test.
How to Check a Manometer The manometer function sets the Product up as a pressure gauge to measure pressure supplied by an external source.
To measure pressure:
1. Connect the pressure port to a pneumatic system as shown in Figure 43.
ProSim 8
SqueezePressure Pump
Blood PressureGauge
glh050.eps
Figure 43. Manometer Connections
2. From the NIBP screen, push the Tests softkey.
3. Push or to highlight Manometer.
4. Push .
The digital pressure screen in Figure 44 is shown in the display.
glh011.bmp
Figure 44. Manometer Screen
As the external generator increases the pressure, the digital and analog pressure values in the display shows the current pressure.
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51
SpO2 Simulation The SpO2 simulation is used to measure the performance of a pulse oximeter for a number of patient conditions. This function lets you to set a combination of blood-oxygen levels, heart rates, and pulse amplitude as well as set an ambient light artifact.
Note
When the Type value is set to Masimo Rainbow, there will be more SpO2 parmaters shown in the display than other types of sensors. See the How to Simulate Masimo a Rainbow SpO2 section to learn about these parameters.
To set SpO2 simulation parameters, push to show the screen in Figure 45 in the display.
glh018.bmp
Figure 45. SpO2 Simulation Screen
Connect the SpO2 artificial finger to the SpO2 jack on the front panel as shown in Figure 46.
ProSim 8
ProSimSpO2 Simulator
SpO2 Cable
PulseOximeterSensor
PatientMonitor
glh029.eps
Figure 46. SpO2 Simulation Connections
Note
When you put the oximeter sensor on the artificial finger, make sure the red LEDs (light emitting diodes) are on the bottom.
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Put the SpO2 sensor on the artificial finger as shown in Figure 47. Place the sensor with the LEDs on the bottom of the artificial finger. While you put the sensor on the artifical finger, monitor the signal indicator along the bottom of the Product display. Adjust the sensor on the finger for maximum signal strength.
F1 F2 ENTERF3 F4 F5
ProSim 8
ProSimSpO2 Simulator
Adjust finger on the display for maximum signal.
SpO2 Cable
PulseOximeterSensor
ToPatientMonitor
glh048.eps
Figure 47. SpO2 Sensor Placement
Attach the artificial finger to the magnetic holder on the right side of the Product as shown in Figure 48.
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ProSim 8
SpO2 SimulatorFinger Module
glh045.eps
Figure 48. Magnetic Holder for SpO2 Artificial Finger
How to Set the SpO2 Parameters You can raise or lower the simulated degree of oxygen saturation. To change the SpO2 value:
1. Push or to highlight the SpO2 value.
2. Push .
3. Push or to increase or decrease the SpO2 value in 1 % steps between 30 and 100 %.
4. Push to set that SpO2 value and go back to the SpO2 screen.
To change the perfusion value:
1. Push or to highlight the Perfusion value.
2. Push .
3. Push or to change the perfusion value between 0 and 20 %. Each push of a key changes the value 0.01 % between 0 and 1 % in the direction of the key pushed. The value changes 0.1 % between 1 and 10 %. The value changes 1 % between 10 and 20 %.
4. Push to set the perfusion value and go back to the SpO2 screen.
To change the transmission value:
1. From the SpO2 screen, push or to highlight the Transmission value.
2. Push .
3. Push or to highlight Dark, Thick Finger, Medium Finger, Light, Thin Finger, and Neonatal Foot.
4. Push to set that transmission value and go back to the SpO2 screen.
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You can change the simulated heart rate of the Product from the SpO2 screen. To change the heart rate:
1. Push or to highlight the Heart Rate value.
2. Push .
3. Push or to adjust the heart rate. Each push of a key moves the heart rate one beat in the direction of the key pushed. The range is 10 to 300 beats/minute (BPM).
4. Push to go back to the SpO2 screen.
To change SpO2 respiration:
1. From the SpO2 screen, push the or to highlight the Respiration value.
2. Push .
3. Push or to highlight 1%, 2%, 3%, 4%, 5% or off.
4. Push to set the respiration and go back to the SpO2 screen.
You can simulate SpO2 under different ambient light conditions. To change the ambient light value:
1. From the SpO2 screen, push the or to highlight the Ambient Light value.
2. Push .
3. Push or to highlight an ambient light value. Below is the list of ambient light values in the Product.
Sunlight Indoor – 4 kHz
Indoor – DC Indoor – 5 kHz
Indoor – 50 Hz Indoor – 6 kHz
Indoor – 60 Hz Indoor – 7 kHz
Indoor – 1 kHz Indoor – 8 kHz
Indoor – 2 kHz Indoor – 9 kHz
Indoor – 3 kHz Indoor – 10 kHz
4. Push to go back to the SpO2 screen with the new ambient light value.
The manufacturer must be known before you do a pulse oximeter test, optically through an artificial finger. For Masimo, you need to know if the sensor is a 2 wavelength or Rainbow sensor. You can configure the Product for the make of pulse oximeter(s) used for the test. You change variables for each of the pulse oximeters through the type variable. To change the oximeter sensor type:
1. From the SpO2 screen, push the or to highlight the Type value.
2. Push .
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3. Push or to highlight a type value in the list. Below is the list of types in the Product.
Nellcor Philips
Masimo Hihon Khoden
Masimo Rainbow Mindray
Nonin BCI
GE/Ohmeda
4. Push to set the type value and go back to the SpO2 screen.
To test other manufacturer types of oximeters, you must download R-Curve data into the Product through the USB Port. Oximeter R-Curve design and data download is done through the Ansur functionality.
How to Simulate a Masimo Rainbow SpO2 When you set the SpO2 type parameter to Masimo Rainbow, you must connect the Product to the monitor with the optional SpO2 Masimo Rainbow cable. See the Optional Accessories table for a part number. The SpO2 screen shows three more parameters than what is shown for other types of sensors: SpMet, SpCO, and SpHb.
SpMet, SpCO, and SpHb can not be set through the Product. The special Masimo Rainbow cable sets them based on the measured SpO2 percent. At 100 %, SpMet = 0 %, SpCO = 0 %, and SpHb = 25 g/dl. A -1 % change in SpO2 changes SpMet +0.3 %, SpCO by +0.7 %, and SpHb by -0.5 %. SpHb does not change for values of SpO2 above 90 %.
How to Perform an Oximeter Limits Test Most oximeters have alarms that can be set for the parameters it measures. The Product can be used to trip the alarm as a test. Connect the Oximeter to the Product as shown in Figure 46.
Oxygen Limits Test You do a sensitivity test on an oximeter through SpO2 value adjustments. To do an oxygen limits test:
1. Set the oxygen alarm limit value(s) on the oximeter.
2. From the SpO2 screen, push or to highlight the SpO2 value.
3. Push .
4. Push to increase the simulated oxygen saturation until the oximeter alarm sounds.
5. Push to decrease the simulated oxygen saturation until the oximeter alarm sounds.
Pulse Rate Test You can simulate different patient conditions while you monitor the effect of different pulse rates on the SpO2 measurement. To do a pulse rate test:
1. Set the pulse rate alarm limit value(s) on the oximeter.
2. From the SpO2 screen, push or to highlight the Heart Rate value.
3. Push .
4. Push to increase the heart rate until the alarm sounds.
5. Push to decrease the heart rate until the alarm sounds.
You can decrease the heart rate to 0 bpm to simulate asystole or no pulse.
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Pulse Amplitude/Perfusion Test The peak-to-peak amplitude of the blood pressure wave simulated by the Product can be increased or decreased. You can decrease the amplitude to find where the oximeter fails to sense a pulse. To do a pulse amplitude test:
1. From the SpO2 screen, push or to highlight the Perfusion value.
2. Push .
3. Push to decrease the perfusion value until the oximeter no longer shows a pulse or the oximeter alarm sounds.
Autosequences Autosequences are a series of steps that change the output of the Product automatically. For example, to do a temperature test on a monitor, you must change the temperature of the temperature simulation a number of times for a specified time period. To do this manually, you can go to the temperature function, push and then push or to change the temperature and then push again. After some time period, you do these same steps for the subsequent temperature change. The Temperature autosequence does these changes for you automatically. Each step of the temperature autosequence sets the temperature and after the allotted time period, it does the subsequent step.
Table 14 is a list of autosequences that are built into the Product.
Table 14. Autosequences
Autosequence Sequence Steps Run Time
ECG 80 bpm, IBP1 120/80 mmHg (Art), IBP2 120/0 (LV), SpO2 100%, NIBP 120/80, Respiration 20 brpm, and Temperature 37 °C
01:00
ECG 250 bpm, IBP1 255/195 (Art), IBP2 255/0 (LV), SpO2 85%, NIBP 255/195, Respiration 80 brpm, and Temperature 42 °C
01:00
ECG 30 bpm, IBP1 35/15 (Art), IBP2 35/0 (LV), SpO2 50%, NIBP 35/15, Respiration 10 brpm, and Temperature 30 °C
01:00
Monitor Testing
REPEAT Total Time 03:00
ECG 80 bpm, IBP1 120/80 (Art), IBP2 120/0 (LV), SpO2 98%, NIBP 120/80, Respiration 20 brpm, and Temperature 37 °C
01:00
ECG 120 bpm, IBP1 250/150 (Art), IBP2 200/0 (LV), SpO2 85%, NIBP 120/150, Respiration 60 brpm, and Temperature 40 °C
01:00
ECG 30 bpm, IBP1 60/30 (Art), IBP2 60/0 (LV), SpO2 50%, NIBP 60/30, Respiration 10 brpm, and Temperature 34 °C
01:00
Medical Training
REPEAT Total Time 03:00
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Table 14. Autosequences (cont.)
Autosequence Sequence Steps Run Time
SpO2 100%, Perf 20%, Medium Finger 00:45
SpO2 85%, Perf 5%, Dark/Thick Finger 00:45
SpO2 50%, Perf 0.5%, Dark/Thick Finger 00:45 Oximeter Testing
STOP Total Time 02:15
NSR (Adult) 80 bpm 00:45
Premature PVC1 Left Vent 00:30
Ventricular Mono VTach 00:30
Ventricular Ventricular Fibrillation 00:30
Ventricular Asystole 00:25
Cardiac Failure
STOP Total Time 02:30
NSR (Adult) 80 bpm 00:20
NSR (Adult) 120 bpm 00:20
Supraventricular Supra VTach 00:20
Ventricular Bigeminy 00:20
TV Paced Asynchornous 75 bpm 00:15
Ventricular Asystole 00:15
Conduction Lt Bndl Branch Block 00:15
Ventricular Run of PVCs 00:30
Supraventricular Atrial Fibrillation 00:15
Ventricular Ventricular Fibrillation 00:15
Arrhythmia Sequences
REPEAT Total Time 03:05
NSR (Adult) 50 bpm 00:30
NSR (Adult) 90 bpm 00:30
NSR (Adult) 120 bpm 00:30
NSR (Adult) 150 bpm 00:30
NSR (Adult) 90 bpm 00:30
NSR (Adult) 70 bpm 00:30
Exercise
REPEAT Total Time 03:00
Respiration 110 bpm 00:30
Respiration 110 bpm 00:30
Respiration 110 bpm 00:30
Respiration 110 bpm 00:12
Respiration Sequence
REPEAT Total Time 01:42
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Table 14. Autosequences (cont.)
Autosequence Sequence Steps Run Time
NIBP 120/80 (93) mmHg 01:00
NIBP 200/150 (167) mmHg 01:00
NIBP 60/30 (40) mmHg 01:00
Premature Atrial PAC 01:00
Ventricular PVCs 01:00
Supraventricular Atrial Fibrillation 01:00
NIBP Sequence
STOP Total Time 06:00
IBP 1: 120/80 mmHg (Art), 2: 120/0 mmHg (LV) 01:00
IBP 1: 25/0 mmHg (RV), 2: 120/80 mmHg (Art) 01:00
IBP 1: 25/10 mmHg (PA), 2: 10/2 mmHg (PAW) 01:00 IBP Sequence
REPEAT Total Time 03:00
Temperature 30.0 °C 00:20
Temperature 34.0 °C 00:20
Temperature 37.0 °C 00:20
Temperature 42.0 °C 00:20
Temperature Sequence
STOP Total Time 01:20
How to View the Steps of an Autosequence To view an autosequence:
1. Push .
2. Push , , , or to highlight Autosquences.
3. Push .
4. Push or to highlight an autosequence in the list. See Table 14.
5. Push .
The screen shown in Figure 49 is the Temperature Sequence in the autosequence list.
glh032.eps
Figure 49. Autosequence Start Screen
The details of the autosequence shows the sequence does each of the four steps and stops.
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Although this example does not repeat, some autosequences do. The screen also shows the four-step sequence will complete in 1 minute and 20 seconds.
Each sequence step is shown in the display. When there are more steps than can be shown in one display screen, push or to go to the next or previous screen.
How to Do an Autosequence To do an autosequence:
1. Push .
2. Push , , , or to highlight Autosquences.
3. Push .
4. Push or to highlight an autosequence in the list.
5. Push the Start softkey. The autosequence screen in Figure 50 shows in the display.
glh033.bmp
Figure 50. Autosequence Step Screen
The autosequence screen shows all the simulation parameters which are updated as the Product steps through the sequence. The right part of the screen shows which step the sequence is on and how much time is left to complete the step. The length of time left to complete all steps of the autosequence is also shown in the display.
Push the Next softkey to abort the step and move to the subsequent step. When the autosequence has moved to step two, a Previous softkey shows in the display. Push the Pause softkey to pause the step. A Continue softkey shows in the display when the auto sequence is paused. Push the Continue softkey to continue the step for the time left when the step was paused.
To abort the autosequence, push the Stop softkey and go back to the Autosequence view screen.
You can not change a pre-defined autosequence or rename it. But, you can use the Ansur functionality to copy an autosequence, make changes, and then put it into the Product as a new custom autosequence. You can change each step of the new autosequence and add more steps as necessary.
How to Save and View Test Results (ProSim 8 only) The data of test results can be saved in and recalled from the Product. Test results are organized in memory first by operator ID, then by a test record ID, and then individual test results. Figure 51 shows the memory organization of test results data.
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Operator: John Doe
Test Record ID: ABC123 1/20/2011
Test Results 001Test Results 002Test Results 003 • • •
Test Record ID: XYZ987 1/31/2011
Test Results 001Test Results 002Test Results 003 • • •
Operator: Jane Doe
Test Record ID: ABC123 1/15/2011
Test Results 001Test Results 002Test Results 003 • • •
Test Record ID: DEF456 1/15/2011
Test Results 001Test Results 002Test Results 003 • • •
glh044.eps
Figure 51. Memory Organization of Test Results
How to Make an Operator ID Test results are kept in memory by an operator ID. To make a new operator ID:
1. Push .
2. Push or to highlight Test Record ID in the list.
3. Push to open the Test ID screen shown in Figure 52.
glh036.bmp
Figure 52. Operator ID Screen
4. Push the Change Operator softkey to open the change operator screen shown in Figure 53.
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glh037.bmp
Figure 53. Change Operator ID Screen
5. Push , , , and to highlight a character for the operator ID.
6. Push to add the highlighted character to the operator ID.
7. Do steps 5 and 6 for each character in the operator ID. You can have the maximum number of characters that fit in the test ID field in the display. If you use more of the narrow characters like I and 1, you can have more characters in the operator ID than when wider characters are used.
8. Push the Done softkey when you have all the characters in the operator ID.
Note
If this is a new operator ID, the ID won’t exist until you save the first test result.
Do these same steps when you change the operator ID to an ID that is already in memory. After you type the ID in as it already is in memory, all saved results data are added to that operator ID.
How to Make a Test ID As shown in Figure 51, test results data is related to a Test Record ID. This test record ID could identify the device under test. Some examples could be its model number, its serial number, or its asset number. After you input the new Test ID, all results data saved after that point is kept with that test ID until you change the test ID.
Note
When you type in a new test ID, the test ID that was open before is closed and no more test results data can be added to that test ID. You can use the same test ID name as one that is already in memory, but a date and time stamp will always be appended to the name and its own test ID.
To make a test ID:
Note
These instructions use the setup function to make a test ID. You can also make a test ID when a Save softkey label shows in the display. The New Test ID softkey always shows in the display when you push the Save softkey.
1. Push .
2. Push or to highlight Test Record ID in the list.
3. Push to open the Test ID screen.
4. Push the New Test ID softkey.
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5. Push , , , and to highlight a character for the test ID.
6. Push to add the highlighted character to the test ID.
7. Do steps 5 and 6 for each character in the test ID. You can have the maximum number of characters that fit in the test ID field in the display. If you use more of the narrow characters like I and 1, you can have more characters in the test ID than when wider characters are used.
Additional characters are available when you push the Special Characters softkey. To go back to the normal characters, push the Back Softkey.
Note
If you make a mistake, push the Back Space softkey to remove the last character added. A Clear All softkey removes all characters in the test ID field of the display.
8. Push the Done softkey when you have all the characters in the test ID.
How to Save Test Results
Note
Before you save test results, make sure the operator ID and test ID are set correctly.
Each function of the Product lets you save test results data through a Save softkey. To save test results:
Note
If the Save softkey label is not shown in the display, it means you can not save data at this point.
1. Push the Save softkey to show the Save screen. The screen in Figure 54 is the save screen for the temperature simulation function.
glh039.bmp
Figure 54. Save Screen
Note
The next step is valid only when the Enter Observed softkey appears in the display.
2. To add measurements shown in the UUT display to the test results record, push the Enter Observed softkey.
Note
If there is more than one simulation parameter, you have to highlight a parameter and push before the next step.
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3. Push or to set the parameter to the value observed on the UUT.
4. Push to set the observed value and show the save screen shown below in the display.
glh049.bmp
Figure 55. Observed Results Screen
Note
If the observed value is incorrect at this point, you can push the Enter Observed softkey and change the observed parameter.
5. Test results are saved with a Pass or Fail prefix in their label. Push the Save as Pass or the Save as Fail softkey. The saving screen in Figure 56 shows in the display.
glh040.bmp
Figure 56. Saving Screen
The three-digit number is the test result ID. Within the test ID, each saved test results is assigned a number in sequence. When the save operation completes, the display goes back to the screen for the function you just saved. In the case of this example, the display goes back to the temperature screen.
How to View Test Results To view the test results in memory:
1. Push .
2. Push , , , and to highlight View Memory.
3. Push .
Note
If no test results data is saved to memory, an error message shows in the display when you push .
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4. Push or to highlight an operator.
5. Push .
Note
If there is only one operator, the operator list does not show in the display and the Product skips steps 4 and 5.
6. The list of test IDs shows in the display. Figure 57 shows an example list of test IDs.
glh041.bmp
Figure 57. Test ID Screen
7. Push or to highlight a test ID record.
8. Push to show the test results data saved for the test ID. See Figure 58.
glh042.bmp
Figure 58. Test Results Screen
9. Push or to highlight a test results file.
10. Push to show the test results data shown in Figure 59.
glh043.bmp
Figure 59. Test Results Data Screen
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How to Print Test Results With a PCL5 compatible printer connected to the USB A Controller Port, you can print a test results record.
Note
A compatible printer must be connected to the Product before the Print softkey appears in the view screen of a test results record.
1. Do the steps in the How to View Test Results section to show a test results record in the display.
2. Push the Print softkey.
The data in the test results record shown in the display is transmitted through the printer port.
How to Delete Saved Data Removal of data from memory is done through the View Memory feature. You can only delete test ID records. When the test ID record is deleted, all saved test results data connected to that test ID is deleted from memory. To remove a test ID record:
1. Push .
2. Push , , , and to highlight View Memory.
3. Push .
4. Push or to highlight an operator.
5. Push .
Note
If there is only one operator, the operator list does not show in the display and the Product skips steps 4 and 5.
6. Push or to highlight a test ID record.
7. Push the Delete softkey to delete the test ID record.
A Confirm Delete screen shows in the display with a “Delete Record?” message. When you push the Yes softkey, the test ID record is deleted from memory and the display goes back to the View Memory screen. Push the No softkey to abort the delete.
The Delete All softkey will delete all the test ID records associated with the operator. A Confirm Delete screen shows in the screen with a “Delete ALL records for this operator?” message.
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Setup Features The Product has several functions that are accessed through the SETUP key. Push to show the setup variables shown below in the display.
glh016.bmp
Figure 60. Setup Screen
The setup parameters are kept in memory and are non-volatile.
How to Set the Time and Date The date and time can be set as well as the format in which they show in the display. From the Setup screen, push or to highlight Date/Time Settings and then push . To go back to the Setup screen, push the Back softkey.
To set the date:
1. Push or to highlight the Date value.
2. Push .
3. Push or to move to the month, day, or year.
4. Push or to increase or decrease the value.
5. Push to set the date and go back to the Date/Time Settings screen.
To set the time:
1. Push or to highlight the Time value.
2. Push .
3. Push or to move to the hour, minute, or second value.
4. Push or to increase or decrease the value.
5. Push to set the time and go back to the Date/Time Settings screen.
To set the date format:
1. Push or to highlight the Date Format value.
2. Push .
3. Push or to highlight the Date Format value.
4. Push to set the date and go back to the Date/Time Settings screen.
To set the time format:
1. Push or to highlight the Time Format value.
2. Push .
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3. Push or to highlight the Time Format value.
4. Push to set the format and go back to the Date/Time Settings screen.
How to Set the Backlight Intensity The backlight on the Product has two intensity levels: Low and High. Each intensity can be set separately. From the Setup screen, push or to highlight Display Settings and push . To go back to the Setup screen, push the Back softkey.
To set the backlight intensity:
1. Push .
2. Push or to highlight a backlight value.
3. Push or to increase or decrease the backlight intensity.
4. Push to set the backlight intensity and go back to the Display Settings screen.
How to Set the Beeper The Product beeper can be turned on and off and its volume set. From the Setup screen, push or to highlight Sound Settings and push . To go back to the Setup screen, push the Back softkey.
5. Push .
6. Push .
7. Push or to highlight On or Off.
When the beeper is set to on, two more variables appear in the Sound Settings screen.
To set the beeper type:
1. Push or to highlight the Beep Type value.
2. Push .
3. Push or to highlight the Beeper Type value.
The beeper can be set to beep at each key press or to beep only when an error occurs.
4. Push to go back to the Sound Settings screen.
To set the beeper volume:
1. Push or to highlight the Volume value.
2. Push .
3. Push or to highlight the Volume value.
4. Push to set the volume and go back to the Sound Settings screen.
How to Set the Pressure Units and IBP Sensitivity The units of measure for pressure (IBP and NIBP) values and IBP sensitivity to simulate are set through the pressure Settings. From the Setup screen, push or to highlight IBP Settings in the setup list and push . To go back to the Setup screen, push the Back softkey.
To set the IBP sensitivity:
1. Push or to highlight the IBP Sensitivity value.
2. Push .
3. Push or to highlight a sensitivity value.
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4. Push to set the sensitivity and go back to the Pressure Settings screen.
To set the Pressure units:
1. Push or to highlight the Units value.
2. Push .
3. Push or to highlight mmHg or kPa.
4. Push to set the units and go back to the IBP Settings screen.
How to Set Battery Settings To help save battery life, the Product can be set to power down (Auto power off) when no buttons are sensed as pushed for a set period of time. You can also set whether or not the battery charges in the Product. From the Setup screen, push or to highlight Battery Settings and push . To go back to the Setup screen, push the Back softkey.
To set auto power off:
1. Push or to highlight the Auto Power Off value.
2. Push .
3. Push or to highlight an auto power off value.
When enabled, auto power of can be set to 10, 30, or 60 minutes.
4. Push to set auto power and go back to the Battery Settings screen.
To set the battery charger:
1. Push or to highlight the Charge Battery value.
2. Push .
3. Push or to highlight Yes or No.
4. Push to set the charger value and go back to the Battery Settings screen.
Note
A 1-minute warning message will show in the display before the Product turns off.
How to Set the Display Language The Product can be set to show text and messages in the display in many different languages. To set the language, push or to highlight Instrument Information in the Setup screen and push . To go back to the Setup screen, push the Back softkey.
The language already set in the Product, shows in the display. To change the language:
1. Push .
2. Push or to highlight a language in the list. Below is a list of the display languages.
English Spanish
French Japanese
Italian Chinese
German
3. Push .
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How to Control the Product Remotely Ansur test automation systems uses a solutions-based procedure for medical device tests. Ansur helps you make standard work through test templates and/or sequences that use your written test procedure. All test results are then integrated into one test report that can be printed or archived. Ansur manages your test procedures through manual and visual automated test sequences.
The software works hand-in-hand with Fluke Biomedical analyzers and simulators, that integrates:
• Visual inspections • Preventive maintenance • Work procedures • Performance tests • Safety tests
Ansur software uses plug-in modules to interface with a wide array of Fluke Biomedical instruments. The plug-in module is a software interface to the Ansur test program. Plug-ins supply test elements used by Ansur Executive that use the same user interface for all analyzers and simulators supported by an Ansur plug-in.
When you purchase a new Fluke Biomedical analyzer or simulator, you can update your existing Ansur software by installing a new plug-in. Each plug-in module allows you to work only with the options and capabilities you need for the instrument you are testing.
Maintenance The Product is a calibrated measurement instrument. Try to prevent mechanical abuse that could change the calibrated values. The Product has no internal user-serviceable parts.
Warnings For safe operation and maintenance of the Product:
• Do not keep cells or batteries in a container where the terminals can be shorted.
• Connect the battery charger to the mains power outlet before the Product.
• Repair the Product before use if the battery leaks.
• Remove batteries to prevent battery leakage and damage to the Product if it is not used for an extended period.
• Keep cells and battery packs clean and dry. Clean dirty connectors with a dry, clean cloth.
• Do not short the battery terminals together.
• Use only Fluke Biomedical approved power adapters to charge the battery.
To prevent personal injury:
• Do not disassemble the battery.
• Batteries contain hazardous chemicals that can cause burns or explode. If exposure to chemicals occurs, clean with water and get medical aid.
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• Do not put battery cells and battery packs near heat or fire. Do not put in sunlight.
• Do not disassemble or crush battery cells and battery packs.
To prevent possible electrical shock, fire, or personal injury:
• Remove the input signals before you clean the Product.
• Use only specified replacement parts.
• Have an approved technician repair the Product.
How to Clean the Product
Caution
Do not pour fluid onto the Product surface; fluid seepage into the electrical circuitry may cause the Product to fail.
Caution
Do not use spray cleaners on the Product; such action may force the cleaning fluid into the Product and damage electronic components.
Clean the Product occasionally with a damp cloth and mild detergent. Try to prevent the entrance of liquids.
Clean the adapter cables with the same precautions. Examine them for damage and deterioration of the insulation. Examine the connections for integrity. Keep the transducer adapter clean and dry.
Battery Maintenance For peak battery performance, charge the Product to maximum charge once a month. If the Product is not to be used for more than a month, keep it connected to the charger.
Note
To get the specified performance, use the specified battery charger that comes with this Product.
When the battery gets low, a low battery message shows in the display.
When the battery discharges to 3 % of full charge, a different message shows and the NIBP function is disabled.
How to Charge the Battery The battery charge level is shown in the upper-right corner of the display when the battery pack is installed in the Product. If the battery has a full charge, shows in the upper right corner of the display. When the battery charges, the four battery level indicators cycle continuously from no bars () to all four bars (). With the AC/DC power supply removed from the Product, the battery icon shows the charge level.
The battery can be charged while it is in or out of the Product. The charge rate is slower when the Product is energized and the battery charger is on. To charge the battery:
1. As shown in Figure 61, connect the AC/DC power supply to the power connector on the battery pack.
2. Connect the AC/DC power supply to a power source.
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Note
When the battery pack is installed in the Product, ensure the battery charger is enabled. See the How to Set Battery Settings section earlier in the manual to enable and disable the battery charger.
The battery charge LED on the battery pack shows red or green when the battery charges. When the LED is green, the battery is charged.
When you have two or more battery packs, you can charge one battery externally while you use the other to energize the Product.
Battery ChargeIndicator
Battery LED
glh047.eps
Figure 61. External Battery Charging Connections
When the battery pack is removed from the Product, push the button below the charge level indicators to see the battery charge level. See Figure 61.
Battery Removal The battery pack is easy to remove and replace. To remove the battery pack:
1. Push down on the battery pack latch as shown in Figure 62.
2. Remove the battery pack from the Product.
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PushDown
Pull Out
glh046.eps
Figure 62. Battery Removal
To put the battery pack into the Product, align the battery pack with the guides on the Product and push it into the Product until the latch locks.
General Specifications Temperature
Operating ............................................................ 10 °C to 40 °C (50 °F to 104 °F)
Storage ............................................................... -20 °C to +60 °C (-4 °F to +140 °F)
Humidity................................................................. 10 % to 90 % non-condensing
Altitude................................................................... 3,000 meters (9,843 ft)
Size (L x W x H) ..................................................... 30.22 cm x 14.48 cm x 8.64 cm (11.9 in x 5.7 in x 3.4 in)
Display ................................................................... LCD Color Display
Communication
USB Device Upstream Port ................................ Mini-B connector for control by a computer
USB Host Controller Port .................................... Type A, 5 V output, 0.5 A max load. Connector for keyboard, barcode reader, and printer
Wireless (ProSim8 Only) .................................... IEEE 802.15.4 for control by a computer
USB Device Virtual COM Port Settings
Baud Rate....................................................... 115,200 bps
Data bits.......................................................... 8 data bits
Stop Bits ......................................................... 1 stop bit
Flow Control.................................................... Hardware (RTS/CTS)
Power ..................................................................... Lithium-Ion rechargeable, 7.2 V, 31 Wh battery
Battery Charger..................................................... 100 to 240 V, 50/60 Hz input, 15 V/2.0 A output. For best performance, the battery charger should be connected to a properly grounded ac receptacle
Battery Life ............................................................ 9 hours (minimum), 100 NIBP cycles typical
Weight .................................................................... 1.81 kg (4 lb)
Safety Standards................................................... EN/IEC 61010-1:2001
Certifications ........................................................., ,
Electromagnetic Compatibility (EMC)................. EN 61326-1:2006
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73
Detailed Specifications Normal-Sinus-Rhythm Waveform ECG Reference...................................................... The ECG amplitudes specified are for Lead II (calibration), from the
baseline to the peak of the R wave. All other leads are proportional.
Normal Sinus Rhythm .......................................... 12-lead configuration with independent outputs referenced to right leg (RL). Output to 10 Universal ECG Jacks, color-coded to AHA and IEC Standards.
High-Level Output................................................. 0.2 V/mV ±5 % of the ECG amplitude setting available on a BNC connector.
Amplitude .............................................................. 0.05 mV to 0.5 mV (0.05 mV steps); 0.5 mV to 5.0 mV (0.25 mV steps)
Amplitude Accuracy ............................................. ±(2 % of setting + 0.05 mV)
ECG Rate
ProSim 8 ............................................................. 10 to 360 BPM in 1 BPM steps
ProSim 6 ............................................................. 30 to 360 BPM in 10 BPM steps
Rate Accuracy ....................................................... ±1 % of setting
ECG Waveform Selection..................................... Adult (80 ms) or pediatric (40 ms) QRS duration
ST-Segment Elevation .......................................... Adult mode only. -0.8 mV to +0.8 mV (0.1 mV steps) Additional steps: +0.05 mV and -0.05 mV
Power-On Default.................................................. 60 BPM, 1.0 mV, adult QRS and ST-segment elevation of 0 mV
Pacemaker Waveform Pacer-Pulse
Amplitude .......................................................... 0 (off), ±2, ±4, ±6, ±8, ±10, ±12, ±14, ±16, ±18, ±20, ±50, ±100, ±200, ±500, and ±700 mV for lead II (reference lead)
Accuracy
Reference lead II ............................................ ±(5 % setting + 0.2 mV)
All other leads ................................................. ±(10 % setting + 0.4 mV)
Pacer-Pulse Width ................................................ 0.1, 0.2, 0.5, 1.0, and 2.0 ms ±5 %
Paced Arrhythmias ............................................... Atrial 80 BPM Asynchronous 75 BPM Demand with frequent sinus beats Demand with occasional sinus beats Atrio-Ventricular sequential Noncapture (one time) Nonfunction
Power-On Default.................................................. Amplitude 10 mV, width 1.0 ms, atrial waveform
Arrhythmia Baseline NSR......................................................... 80 BPM
PVC Focus ............................................................. Left focus, standard timing (except where specified)
Supraventricular Arrhythmia
ProSim 8 ............................................................. Atrial fibrillation (coarse or fine); atrial flutter; sinus arrhythmia; missed beat (one time); atrial tachycardia; paroxysmal atrial tachycardia; nodal rhythm; and supraventricular tachycardia.
ProSim 6 ............................................................. Atrial fibrillation (coarse or fine) and sinus arrhythmia
Premature Arrhythmia
ProSim 8 ............................................................. Premature atrial contraction (PAC); premature nodal contraction (PNC); PVC1 left ventricular; PVC1 left ventricular, early; PVC1 left ventricular, R on T; PVC2 right ventricular; PVC2 right ventricular, early; PVC2 right ventricular, R on T; and multifocal PVCs
ProSim 6 ............................................................. Premature atrial contraction (PAC) and multifocal PVCs
Ventricular Arrhythmia
ProSim 8 ............................................................. PVCs 6, 12, or 24 per minute; frequent multifocal PVCs; bigeminy; trigeminy; multiple PVCs (one-time run of 2, 5, or 11 PVCs); mono-ventricular tachycardia (120 to 300 BPM in 5 BPM steps); poly-ventricular tachycardia (5 types); ventricular fibrillation (coarse or fine); and Asystole
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ProSim 6 ............................................................. Bigeminy; mono-ventricular tachycardia (120 to 300 BPM in 5 BPM steps); poly-ventricular tachycardia (5 types); ventricular fibrillation (coarse or fine); and Asystole
Conduction Defect
ProSim 8 ............................................................. First-, second-, or third-degree heart block; and right- or left-bundle-branch block
ProSim 6 ............................................................. Second-degree heart block, type 1, and right-bundle-branch block
Advanced Cardiac Life Support (ProSim 8 only)
Shockable Pulseless Arrest Rhythms................. Ventricular fibrillation (coarse), ventricular fibrillation (fine), unstable polymorphic ventricular tachycardia
Non Shockable Pulseless Arrest Rhythms ......... Asystole
Symptomatic Bradycardia................................... Sinus Bradycardia (<60 BPM) 2nd Degree AV Block, Mobitz Type I 2nd Degree AV Block, Mobitz Type II Complete/3rd Degree AV Block Right Bundle Branch Block Left Bundle Branch Block
Symptomatic Tachycardia
Regular Narrow-complex Tachycardias (QRS <0.12 seconds)
Sinus Tachycardia ...................................... >150 BPM
Supraventircular Tachycardia ..................... SVT
Regular Wide-complex Tachycardias (QRS ≥0.12 seconds)
Sinus Tachycardia ...................................... >150 BPM
Supraventircular Tachycardia ..................... SVT with aberrancy
Irregular Tachycardia...................................... Atrial Fibrillation (Coarse and fine), Atrial Flutter, unstable monomorphic ventricular tachycardia (120 to 300 BPM), Torsade De Pointes/Polymorphic ventricular tachycardia (long QT interval)
ECG-Performance-Testing Amplitude (peak-to-peak)..................................... 0.05 to 0.5 mV (0.05 mV steps)
0.5 to 5.0 mV (0.25 mV steps)
Pulse Wave ............................................................ 30, 60 BPM, with 60 ms pulse width
Square Wave ......................................................... 0.125, 2.0, 2.5 Hz
Triangle Wave........................................................ 0.125, 2.0, 2.5 Hz
Sine Wave .............................................................. 0.05, 0.5, 1, 2, 5, 10, 25, 30, 40, 50, 60, 100, and 150 Hz
R-wave Detection (ProSim 8 only)
Waveform............................................................ Triangular pulse
Rate .................................................................... 30, 60, 80, 120, 200, and 250 BPM
Width................................................................... 8 to 20 ms in 2 ms steps, and 20 to 200 ms in 10 ms steps
Width Accuracy................................................... ±(1 % of setting + 1 ms)
QRS Detection (ProSim 8 only)
Widths................................................................. 8 to 20 ms in 2 ms steps and 20 to 200 ms in 10 ms steps
Width Accuracy................................................... ±(1 % of setting + 1 ms)
Rate .................................................................... 30, 60, 80, 120, 200, and 250 BPM
R-Wave up slope ................................................ 0.875 amplitude, 0.4375 x width
R-Wave down slope............................................ Full amplitude, 0.5 x width
S-Wave up slope ................................................ 0.125 amplitude, 0.0625 x width
Tall T-Wave Rejection (ProSim 8 only)
Waveform
QT Interval ...................................................... 350 ms
T-Wave width.................................................. 180 ms
T-Wave Shape................................................ ½ sinewave
Amplitude............................................................ 0 to 150 % reference lead amplitude in 10 % steps
Rate .................................................................... 80 BPM
Rate Accuracy ....................................................... ±1 % of setting
Amplitude Accuracy ............................................. ±(2 % of setting + 0.05 mV)
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ECG Artifact Type........................................................................ 50 Hz, 60 Hz, muscular, baseline wander, respiration
Size......................................................................... 25, 50, 100 % of the normal sinus R-Wave for each lead
Lead Select ............................................................ All, RA, LL, LA, V1, V2, V3, V4, V5, V6
Fetal / Maternal-ECG (ProSim 8 only) Fetal Heart Rate (Fixed)........................................ 60 to 240 BPM in 1 BPM steps
Fetal Heart Rate (IUP): .......................................... 140 BPM at beginning, then varies with pressure
Intrauterine-Pressure Waveforms ....................... Variable deceleration, early deceleration, late deceleration, and acceleration
Wave Duration....................................................... 90 seconds, bell-shaped pressure curve, from 0 to 90 mmHg and returning to 0
IUP Period.............................................................. 2, 3, or 5 minutes; and manual
Default Settings..................................................... FHR 140 BPM, variable deceleration wave, manual
Invasive Blood Pressure Channels................................................................ 2, each independently settable with identical parameters and are
individually electrically isolated from all other signals
Input/output Impedance ....................................... 300 Ω ±10 %
Exciter Input Range .............................................. 2.0 to 16.0 V peak
Exciter-Input Frequency Range........................... DC to 5000 Hz
Transducer Sensitivity ......................................... 5 (default) or 40 μV/V/mmHg
Pressure Accuracy ............................................... ±(1 % of setting + 1 mmHg)
Static Pressure...................................................... -10 to +300 mmHg in 1 mmHg steps
Pressure Units....................................................... mmHg or Kpa
Dynamic Waveforms
Types (default pressures) ................................... Arterial (120/80) Radial artery (120/80) Left ventricle (120/00) Right ventricle (25/00) Pulmonary artery (25/10) Pulmonary-artery wedge (10/2) Right atrium (central venous or CVP) (15/10)
Pressure Variability ............................................. Systolic and diastolic pressures are independently variable in 1 mmHg steps.
Swan-Ganz Sequence........................................... Right atrium, right ventrical (RV), pulmonary artery (PA), pulmonary artery wedge (PAW)
Cardiac Catheterization (ProSim 8 only)
Chambers ........................................................... Aortic, Pulmonary valve, and Mitral valve
Respiration Artifact
Arterial, radial artery, and left ventricle ............... 5 to 10 % multiplication
Other ................................................................... 5 or 10 mmHg
BP Output .............................................................. Circular DIN 5-Pin
Power-On Default.................................................. 0 mmHg
Respiration Rate ........................................................................ 0 (OFF), 10 to 150 BrPM in 1 BrPM steps
Waves..................................................................... Normal or ventilated
Ratio (inspiration:expiration)
Normal ................................................................ 1:1, 1:2, 1:3, 1:4, 1:5
Ventilated............................................................ 1:1
Impedance Variations (Δ Ω) ................................. 0.00 to 1.00 Ω in 0.05 Ω steps and 1.00 to 5.00 Ω in 0.25 Ω steps
Delta Accuracy ...................................................... ±(3 % of setting + 0.05 Ω)
Baseline ................................................................. 500, 1000 (default), 1500, 2000 Ω, Leads I, II, III
Baseline Accuracy ................................................ ±5 %
Respiration Lead................................................... LA or LL (default)
Apnea Selection .................................................... 12, 22, or 32 seconds (one-time events), or continuous (Apnea ON = respiration OFF)
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Power-On Default.................................................. 20 BrPM, delta 1.0 Ω
Temperature Temperature .......................................................... 30.0 °C to 42.0 °C in 0.5 °C steps
Accuracy................................................................ ±0.4 °C
Compatibility ......................................................... Yellow Springs, Inc. (YSI) Series 400 and 700
Output .................................................................... Circular DIN 4-pin
Cardiac Output Catheter Type ........................................................ Baxter Edwards, 93a-131-7f
Calibration Coefficient.......................................... 0.542 (0 °C injectate), 0.595 (24 °C injectate)
Blood Temperature ............................................... 36 °C (98.6 °F) to 38 °C (100.4 °F) ±2 % in 1 °C steps
Injectate Volume ................................................... 10 cc
Injectate Temperature........................................... 0 °C or 24 °C
Cardiac Output ...................................................... 2.5, 5, 10 liters per minute ±5 %
Faulty-Injectate Curve .......................................... Waveform for simulation available
Left-to-Right-Shunt Curve.................................... Waveform for simulation available
Calibrated Pulse.................................................... 1.5 ° for 1 second
Connector .............................................................. Circular DIN 7 pin
Power-On Default ................................................. 5 liters per minute, 0 °C injectate, 37 °C blood temperature
Non-Invasive Blood Pressure Pressure Units....................................................... mmHg or kPa
Manometer (Pressure Meter)
Range ................................................................. 10 to 400 mmHg
Resolution........................................................... 0.1 mmHg
Accuracy
ProSim 8 ......................................................... ±(0.5 % reading +0.5 mmHg)
ProSim 6 ......................................................... ±(1 % reading +1 mmHg)
Pressure Source
Target Pressure Range ...................................... 20 to 400 mmHg
Resolution........................................................... 1 mmHg
NIBP Simulations
Pulse................................................................... 2 mmHg max into 500 ml NIBP system
Volume of air moved........................................... 1.25 ml max
Simulations ......................................................... Systolic/diastolic (MAP)
Adult................................................................ 60/30 (40), 80/50 (60), 100/65 (77); 120/80 (93); 150/100 (117); and 200/150 (167) and 255/195 (215)
Neonatal ......................................................... 35/15 (22); 60/30 (40); 80/50 (60);100/65 (77);120/80 (93) and 150/100 (117)
Pressure variability ......................................... Systolic and diastolic pressures are variable by 1 mmHg
Repeatability ....................................................... Within ±2 mmHg (at maximum pulse size independent of device under test)
Synchronization
Normal Sinus heart rates ................................ 30 to 240 BPM
Maximum rate at 1 ml ................................. 240 BPM achievable with pulses up to 1 ml
Maximum rate at 1.25 ml ............................ 180 BPM
Arrhythmias..................................................... Premature atrial contraction (PAC), Premature ventricular contraction (PVC), atrial fibrillation, and missed beat.
Leak Test
Target Pressure .................................................. 20 to 400 mmHg
Elapsed time ....................................................... 0:30 to 5:00 minutes:seconds in 30 second steps
Range ................................................................. 0 to 200 mmHg/minute
Pressure Relief Test Range ................................. 100 to 400 mmHg
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SpO2 Simulations (optional) % O2
Range ................................................................. 30 to 100 %
Resolution........................................................... 1 %
Accuracy
With oximeter manufacturer’s R-curve
Saturation within UUT specific range.............. ±(1 count + specified accuracy of the UUT)
Saturation outside UUT specific range ........... monotonic with unspecified accuracy
With Fluke Biomedical R-curves
91 to 100 %..................................................... ±(3 counts + specified accuracy of the UUT)
81 to 90 %....................................................... ±(5 counts + specified accuracy of the UUT)
71 to 80 %....................................................... ±(7 counts + specified accuracy of the UUT)
Below 71 %..................................................... monotonic with unspecified accuracy
Heart Rate .............................................................. 30 to 300 BPM in 1 BPM steps. SpO2 simulation is synchronized with ECG rate delayed by 150 ms.
Transmission (Ratio of detector current to LED current, expressed in parts per million (ppm))
Range ................................................................. 0 to 300.00 ppm
Resolution........................................................... 0.01 ppm
Accuracy ............................................................. +50 %/-30 % for compatible monitors, unspecified for others. Selected by finger size and color: Dark, thick finger, medium finger, light, thin finger, neonatal foot.
Perfusion
Range ................................................................. 0 to 20.00 %
Resolution........................................................... 0.01 %
Artifact
Respiration
Range ............................................................. 0 to 5 % of transmission
Resolution....................................................... 1 %
Rate ................................................................ all ProSim respiration simulation settings
Ambient Light
Range ............................................................. 0 to 5X transmitted light
Resolution....................................................... 1X
Frequency....................................................... DC, 50 Hz, 60 Hz, and 1 to 10 kHz in 1 kHz steps
Masimo Rainbow Technology ............................. Simulate Masimo Rainbow technology with an optional adapter supplied by Masimo that allows the ProSim two wavelength simulation to test the Rainbow multiple wavelength system
Compatible Manufacturer Products
With manufacturer R-curve................................. Nellcor, Masimo, Nonin, and Nihon Khoden
With Fluke Biomedical R-curve........................... Mindray, GE-Ohmeda, Philips/HP, and BCI
Pre-Defined Simulations Normal Hypertensive Hypotensive Tachycardic Bradycardic Heart Attack Asystole
Autosequences (default) Monitor testing sequence Medical training sequence Oximeter testing sequence Cardiac failure sequence Arrhythmia sequence Exercise sequence Respiration sequence NIBP testing sequence IBP testing sequence Temperature sequence
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A-1
Appendix A Glossary
Introduction The words in this glossary are common words used in this manual that may need further explanation. Words in italics are words that are defined in this glossary.
AAMI Acronym for the Association for the Advancement of Medical Instrumentation. A group of physicians, biomedical and clinical engineers, nurses, manufacturers, and government representatives who set industry guidelines for the performance and safety of biomedical instrumentation.
AC component The pulse factors of the blood measured by oximetry.
Ampere A unit of steady electrical current which, when flowing in straight parallel wires of infinite length and negligible cross section, separated by a distance of one meter in free space, produces a force between the wires of 2 × 107 newtons per meter of length.
Aorta The main trunk of the systemic arteries, carrying blood from the left side of the heart to the arteries of all limbs and organs except the lungs.
Apnea Apnea is described as the cessation of breathing. In general there are three types of apnea: central (often seen in infants, when there is no diaphragm movement and no air flow); obstructive (where an object, such as food, is lodged in the trachea); and mixed (where central apnea is followed immediately by obstructive apnea).
Artery Any of a branching system of muscular tubes that carry blood away from the heart.
Artifact An abnormal signal or structure produced by an external medium, such as a muscle or electrical wiring. Artifacts are sometimes referred to as noise.
An ECG artifact can be caused by depolarization or contraction of the muscle which depends on an electrical charge. These electrical charges can be detected by an electrocardiogram. The electrical charges associated with the contractions of the heart will be clear only if there is not interference by auxiliary signals from other muscle movement. Electrical signals from power lines or local (in-wall) circuitry represent
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another kind of artifact (also called noise) that can be picked up by an ECG device. These sources can cause minute electric currents through capacitive coupling or resistive contacts. On an ECG readout, such electrical artifacts can cause a serious safety condition. Even a relatively tiny current of 60 hertz (Hz) can be fatal. Therefore, whenever line frequency in an electrocardiogram is noted, the cause of the signal should be determined at once
Asynchronous Signals sent to a computer at irregular intervals. Data is transmitted at irregular intervals by preceding each character with a start bit and following it with a stop bit. Asynchronous transmission allows a character to be sent at random after the preceding character has been sent, without regard to any timing device.
Asystole (Cardiac Standstill) No ECG activity whatsoever. Ventricular asystole is a critical condition characterized by the absence of a heartbeat either in the ventricles or in the entire heart. This condition, also referred to as cardiac standstill, is usually accompanied by loss of consciousness, apnea, and—if not treated immediately—death.
Atrial Fibrillation A rapid, irregular atrial signal, coarse or fine, with no real P waves; an irregularventricular rate. Coarse and fine atrial fibrillation occurs when the electrical signals in the atria are chaotic, and multiple, ectopic pacemakers are firing erratically. Some impulses may conduct through to the AV node to stimulate the ventricles, causing a quite-irregular and often-rapid ventricular rate. On the ECG there is an absence of P waves, with an irregular R-R interval. Atrial-fibrillation waveforms are irregularly shaped and usually rounded. The amplitude of the atrial signal is higher for coarse, and lower for fine, fibrillation.
Atrial Flutter A repeating sequence of large, irregular P waves at 300 BPM; an irregular ventricular response. Atrial flutter occurs when a single, ectopic, atrial pacemaker that is non-SA (usually low, near the AV node) fires repeatedly and (usually) regularly, producing large, pointed P waves at an approximate rate of 400 BPM (between 240 and 480 BPM). Not all of the atrial impulses conduct through to the ventricles. On the ECG readout the waveform generally exhibits a “saw tooth” appearance. This type of arrhythmia can reduce cardiac output by as much as 25 %, due in many cases to the lack of an atrial “kick” and the accompanying failure of the ventricles to fill completely with blood prior to ventricle contraction.
Atrial Tachycardia (AT) Normal rhythm at a faster-than-normal rate of 160 BPM.
Atrial tachycardia occurs when an ectopic, atrial pacemaker (non-SA) fires repeatedly at a rate between 150 and 250 BPM. AT may cause cardiac output to drop significantly (in some cases by as much as 25 %), due to the inability of the ventricles to fill completely during the typically short diastole. This condition may result from an atrioventricular blockage or digitalis toxicity.
Atrium (1) One of the two upper chambers of the heart. (2) Any chamber allowing entrance to another structure or organ.
AV Junction A junction consisting of the AV node and the bundle of His. Conducts the electrical impulse sent from the SA node from the atria into the ventricles.
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AV Node Also called the atrioventricular node. Located in the right atrium near the septum. Conducts the electrical impulse in the heart to the bundle of His, which passes it on to the left- and right-bundle branches.
Baud A unit of measurement that denotes the number of discrete signal elements, such as bits, that can be transmitted per second. Bits-persecond (bps) means the number of binary digits transmitted in one second.
Bigeminy Two sequences: a PVC followed by a normal beat, or a PVC followed by two normal beats. Bigeminy—also called a fixed coupling or bigeminal rhythm—is a type of PVC in which a beat with a normal QRS complex alternates with a PVC; in other words, every other beat is premature. In trigeminy, which is similar to bigeminy, a PVC appears after every two normal QRS complexes.
Blood Pressure The pressure of the blood within the arteries, primarily maintained by contraction of the left ventricle.
BPM Beats per minute. SEE pulse.
Bundle-Branch Block Blockage in the right- or left-bundle branches, with beats exhibiting a wide QRS and a PR interval of 160 ms. Bundle-branch blockage—also referred to as intraventricular conduction defect, BBB or IVCD—is a form of heart block in which there is a conduction delay or failure from one of the branches of the bundle of His (which start about a centimeter below the bundle of His) to the Purkinje network. The blockage may be complete or incomplete, transient, intermittent, or permanent. In most cases, the electrical impulse travels through the normal bundle branch to stimulate one ventricle and then passes through the cardiac septum to stimulate the other, resulting in one ventricle’s depolarizing later than the other. (Both anatomically and functionally, the septum separates the heart into its left and right halves.)
Bundle Of HIS A collection of nerves (about 1 cm in length) that lies just below the AV node in the heart. Part of the heart’s electrical conduction system. With the AV node, forms the AV junction. Below the bundle, the nerves divide into left and right branches.
Computational Constant Pertaining to cardiac output. Sometimes called calibration coefficient.
Cardiac Of, near, or pertaining to the heart.
Cardiovascular Of, pertaining to, or involving the heart and the blood vessels.
Capillary One of the minute blood vessels that connect the arteries and veins.
DC component See R-Value
ECG An electrocardiogram (ECG) records the electrical signals of the muscles of the heart—the depolarization and repolarization of the myocardium. Wires from an ECG machine
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are connected to small plastic or metal disks called leads, or electrodes. Put on the chest, the wrists of the right and left arms, and the left leg at the ankle, these electrodes transmit signals to a recorder. The recorder makes lines in the shape of waves on graph paper in the ECG machine, follow the heart's electrical activity (rate) and its rhythm (beat). Each contraction of a normal heart causes a normal sinus rhythm (NSR) waveform, also referred to as the P QRS T waveform.
Frequent Multifocal PVCS A sequence that includes a left-focus PVC followed by normal beats, alternating with a right-focus PVC followed by normal beats. Frequent multifocal PVCs are initiated by a number of different ectopic pacemakers in the ventricles, with events occurring at least five times per minute, and usually more often.
Gram A metric unit of mass and weight, equal to one-thousandth of a kilogram, about 0.035 ounces.
Heart Block: First, Second, and Third Degree Three heart-block simulations, running as repeating sequences. A heart block is a condition wherein the signal generated by the SA node is delayed or is blocked (partially or completely) in its journey to the ventricles. Because this condition typically occurs at the AV (atrioventicular) junction, a more precise term for heart block is atrioventricular block. When the conduction time from the atria to the ventricles becomes delayed (usually resulting in a P-R interval greater than 0.20 seconds), it is referred to as a first-degree block. When impulses from the atria occasionally do not reach the ventricles, the block is considered partial or incomplete and is referred to as a second-degree block. Finally, when no impulses whatsoever are able to enter the ventricles from the atria, the heart block is complete and is referred to as a third-degree block. As a consequence of a third-degree block, the atria and the ventricles beat at their own separate rates.
Hemoglobin The oxygen-bearing, iron-containing conjugated protein in vertebrate red blood cells, consisting of about 6 per cent heme and 94 per cent globin.
Hertz A unit of frequency equal to one cycle per second. Used to measure electrical current and light, especially ultraviolet radiation (as in fluorescent light).
Impedance A measure of the total opposition to current in a circuit.
Infrared Of, pertaining to, or being electromagnetic radiation having wavelengths greater than those of visible light and shorter than those of microwaves.
Joule A unit of energy, equal to the work done when a current of one ampere is passed through a resistance of one ohm for one second.
Kilogram The fundamental unit of mass in the International System, about 2.2046 pounds.
LCD Liquid crystal display. A digital display consisting of a liquid crystal material between sheets of glass that becomes readable in the presence of an applied voltage.
Meter The fundamental unit of length, equivalent to 39.37 inches, in the metric system.
Glossary Introduction A
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Millivolt One-thousandth of a volt.
Missed Beat A single missing beat, with the heart rate returning to normal. Missed beats, often present in first-degree heart block, are symptomatic of other conditions as well.
Multifocal PVCS A sequence that includes a left-focus PVC, followed by two normal beats, followed by a right-focus PVC, followed by a normal rhythm at 80 BPM. Multifocal PVCs are premature ventricular contractions that originate in different ectopic-pacemaker sites throughout the ventricles. These PVCs, which exhibit different size and shape elements, are characterized by the absence of a P wave (due to the lack of any atrial-pacemaker activity).
Multiple PVCS: Paired PVCS; Run 5 PVCS; Run 11 PVCS Three series of multiple PVCs run as one-time (nonrepeating) events. The term multiple PVCs refers to any condition where two or more PVCs occur in a row. Standard PVCs of this type include a pair of PVCs (also known as a couplet), a run of five PVCs in a row, and a run of eleven PVCs in a row.
Myocardium The thick muscular layer of the heart, located between the endocardium at the inside and the epicardium at the outside walls of the heart.
Nanometer One-billionth (109) of a meter.
Nanosecond One billionth (109) of a second (one thousand-millionth of a second). Electricity travels approximately one foot per nanosecond.
Nodal Rhythm Normal rhythm, but with a P wave that originates in the AV node, and a P-R interval that is very short. Nodal rhythm, also referred to as junctional rhythm or junctional escape, is a condition where the predominant pacemaker is the AV node rather than the SA node.
Noninvasive Not tending to spread; especially, not tending to invade healthy tissue.
Ohm A unit of electrical resistance equal to that of a conductor in which a current of one ampere is produced by a potential of one volt across its terminals.
PAP Pulmonary arterial pressure.
Patient Leads Disks that connect a patient directly with the monitor. Sometimes called applied parts.
Paroxysmal Atrial Tachycardia (PAT) Normal rhythm at alternating rates. When atrial tachycardia occurs as a seizure-like spasmodic event, it is called paroxysmal atrial tachycardia or PAT. PATs typically start and stop suddenly, initiated by a premature atrial contraction (PAC). PAT spasms may last for only a few seconds or for minutes or hours. A patient may experience ATs and PATs over the course of many years.
PCWP Pulmonary capillary wedge pressure. Also known as PAW.
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Premature Atrial Contraction (PAC) A beat that is 25 % premature but otherwise normal. Any part of the heart can depolarize earlier than it should; the accompanying heartbeat is called extrasystole. This type of depolarization is called a premature contraction; a premature contraction that originates in the SA node is referred to as a PAC. An isolated PAC is relatively unimportant. However, frequent PACs are a concern, because they could be the precursor of more serious and potentially life-threatening conditions, including atrial flutter, atrial fibrillation, and atrial tachycardia.
Premature Nodal Contraction (PNC) A nodal beat that is 25 % premature, followed by a nodal rhythm at 80 BPM. A premature nodal contraction—also called a premature junctional contraction, a PNC, or a PJC—is an extra beat that occurs as a result of an electrical impulse sent from the atrioventricular (junctional) node. The P-R interval is shorter than normal. PNCs, which may occur in isolation or in groups, can appear sporadically for no obvious reason in an otherwise-healthy person.
Premature Ventricular Contractions Six PVC-type selections of focus and timing:
• a left-focus premature ventricular beat with standard timing, 20 % premature;
• a left-focus premature ventricular beat with early timing, 33 % premature;
• a left-focus premature ventricular beat with very early timing, 65 % premature, which starts during the T wave of the previous beat;
• a right-focus premature ventricular beat with standard timing, 20 % premature;
• a right-focus premature ventricular beat with early timing, 33 % premature; or
• a right-focus premature ventricular beat with very early timing, 65 % premature, which starts during the T wave of the previous beat.
A premature ventricular contraction or PVC is an extra beat consisting of an abnormally wide and unusual QRS complex originating in an ectopic pacemaker in the ventricles. Early ventricular PVCs occur close to the preceding beat. Moreover, R-on-T PVCs, which are characterized by a beat that falls on the T wave of the preceding QRS-T complex, are especially inauspicious because of their potential to cause ventricular tachycardia or ventricular fibrillation.
Pulse The rhythmical throbbing of arteries produced by regular contractions of the heart.
Pulse Oximeter A non-invasive, arterial, oxygen-saturation monitor that measures the ratio of two principle forms of hemoglobin in the blood.
Purkinje Network The dense collection of Purkinje fibers, which are dispersed throughout the myocardium and which represent the terminal portion of the heart's electrical conduction system.
PVCS Premature ventricular contractions.
PVCS: 6, 12, or 24 Per Minute PVCs scattered among normal beats AT 80 BPM, so that PVCs take place 6, 12, or 24 times every minute. Premature ventricular contractions may occur independently (even in healthy individuals), as well as in groups and/or for a number of times every minute.
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QRS Complex The part of the P-QRS-T wave that records ventricular depolarization and contraction.
R-Value The non-pulsating components of tissue, specifically the tissue bed, the venous blood, the capillary blood, and nonpulsatile arterial blood. Also referred to as the DC component.
Resistance The opposition to electric current that is characteristic of a medium, substance, or circuit element.
SA Node The dominant pacemaker site in the heart, responsible for setting the heart rate. Positioned in the right atrium near the inlet of the superior vena cava.
SaO2 Abbreviation for saturated oxygen, SaO2 is the ratio of the concentration of oxyhemoglobin (cHbO2) to the concentration of the two principle types of blood hemoglobin: saturated hemoglobin (HbO2) plus reduced hemoglobin (Hb).
Serial Port An asynchronous COMmunication port/address to which a peripheral—such as a printer or a mouse—is connected to a computer or other device. SEE RS-232.
Sinus Arrhythmia Beats that are normal, but triggered at an irregular rate, from 60 BPM to 100 BPM.
Sinus arrhythmia occurs when the SA node paces the heart irregularly. Typically, the heartbeat increases with each intake of breath and decreases with each exhalation (a condition most commonly found in young children and the elderly).
SpO2 The type of saturated oxygen measured with a pulse oximeter.
Supraventricular Tachycardia Normal rhythm at a faster-than-normal rate of 200 BPM. Supraventricular tachycardia is a combination of a junctional tachycardia (that is, an atrial tachycardia occurring in the AV or junctional node) and an atrial tachycardia. Therefore, supraventricular tachycardia encompasses multifocal, ectopic, atrial pacemakers in and around the AV node above the bundle of His.
Swan-Ganz A soft, balloon-tipped catheter used for measuring blood pressure and cardiac output. The catheter is guided by blood flow into the pulmonary artery. A monitor near the tip of the catheter detects PAP, PCWP, and thermodilution.
Swan-Ganz Procedure After insertion of a Swanz-Ganz catheter into a vein (usually the basilic vein of the forearm), the catheter is gently guided by the flow of the blood into the pulmonary artery. A monitor attached to the distal lumen port supplies a reading of pulmonary-artery pressure (PAP). Pulmonary-capillary-wedge pressure (PCWP) is determined by inflating the balloon, which becomes wedged; when this wedge blocks blood flow, it provides a reading of the pressure in the left side of the heart.
Thermodilution The measuring of temperature change, enabled by the injection of a cold or room-temperature solution (such as saline) into the right atrium by means of a Swan-Ganz procedure.
ProSim™ 6/8 Users Manual
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Trigeminy A PVC appears after every two normal QRS complexes.
Venous (1) Of or pertaining to a vein or veins. (2) Returning to the heart through the great veins.
Ventricle A small anatomical cavity or chamber, as of the brain or heart, especially (1) the chamber on the left side of the heart that receives arterial blood from the left atrium and contracts to drive it into the aorta, and (2) the chamber on the right side of the heart that receives venous blood from the right atrium and drives it into the pulmonary artery.
Ventricular Fibrillation An irregular ventricular waveform, coarse or fine. Coarse and fine ventricular fibrillations occur when the electrical signals in the ventricles are chaotic, and multiple, ectopic, ventricular pacemakers are firing erratically. There are no real P waves and no clear R-R interval. Ventricular fibrillation waveforms are irregularly shaped. Ventricular fibrillation is a life-threatening condition; usually in such situations a defibrillator is applied immediately to return the heart to its normal rhythm.
Ventricular Tachycardia A faster-than-normal rhythm of beats (160 BPM) originating in the ventricles, similar to type-1 (left-focus) PVCs. Ventricular tachycardia is a life-threatening arrhythmia in which one or multiple, ectopic, ventricular pacemakers in the bundle branches, Purkinje network, or ventricular myocardium are firing in a heart beating more frequently than 110 times a minute. In some cases the heart will be beating at a rate above 240 BPM. Ventricular tachycardia usually occurs in cases of extreme cardiac disease and often initiates or degenerates into ventricular fibrillation. This type of tachycardia can reduce cardiac output by as much as 25 % due, in many cases, to the lack of an atrial “kick” and therefore the lack of a complete filling of the ventricles with blood prior to ventricle contraction.
Volt The International System unit of electric potential and electromotive force, equal to the difference of electric potential between two points on a conducting wire carrying a constant current of one ampere when the power dissipated between the points is one watt.
Waveform (1) The mathematical representation of a wave, especially a graph of deviation at a fixed point (baseline) versus time. (2) On an ECG tracing or output, the size, shape, and distance (in milliseconds) of a P-QRS-T complex.
Wavelength In a periodic wave, the distance between two points of corresponding phase in consecutive cycles.